arroyo toad (anaxyrus californicus) life history
TRANSCRIPT
Arroyo Toad (Anaxyrus californicus) Life History, Population Status, Population
Threats, and Habitat Assessment of Conditions at Fort Hunter Liggett, Monterey
County, California
A Thesis
presented to
the Faculty of California Polytechnic State University,
San Luis Obispo
In Partial Fulfillment
of the Requirements for the Degree
Master of Science in Biology
by
Jacquelyn Petrasich Hancock
December 2009
© 2009 Jacquelyn Petrasich Hancock
ALL RIGHTS RESERVED
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COMMITTEE MEMBERSHIP
TITLE: Arroyo Toad (Anaxyrus californicus) Life History, Population Status, Population
Threats, and Habitat Assessment of Conditions at Fort Hunter Liggett, Monterey County,
California
AUTHOR: Jacquelyn Petrasich Hancock
DATE SUBMITTED: December 2009
COMMITTEE CHAIR: David Pilliod, PhD
COMMITTEE MEMBER: Emily Taylor, PhD
COMMITTEE MEMBER: Scott Steinmaus, PhD
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Abstract
Arroyo Toad (Anaxyrus californicus) Life History, Population Status, Population Threats, and Habitat Assessment of Conditions at Fort Hunter Liggett, Monterey County,
California
Jacquelyn Petrasich Hancock
The arroyo toad (Anaxyrus californicus) is a federally endangered species found on Fort Hunter Liggett, Monterey County, California. The species was discovered in 1996 and was determined to occupy 26.7 km of the San Antonio River from approximately 2.4 km northwest of the San Antonio Mission de Padua, to the river delta above the San Antonio Reservoir. The construction of the San Antonio Reservoir dam in 1963 isolated this northern population of arroyo toads. Through time, the Fort Hunter Liggett landscape has changed drastically. The land was heavily grazed by cattle until 1991, which considerably reduced vegetation in riparian areas. Military training following acquisition of the land in 1940 far exceeded current allowable training. Fire was used extensively to reduce unfavorable vegetation, and as a result, extreme tree loss occurred through the ranges. Today cattle grazing is prohibited and military activity is restricted from riparian corridors. While riparian vegetation continues to recover in the San Antonio River, habitat for breeding arroyo toads has become less suitable. To improve conservation efforts and management of this endangered species, I have provided a thorough assessment of the life history of arroyo toads specific to Fort Hunter Liggett and identified the status and current threats to the population on the installation. I have also prepared a habitat assessment of the San Antonio River in the arroyo toad range, quantified habitat conversion, and identified areas that may no longer provide suitable breeding habitat for the species. The research conducted for this report is preliminary to restoration efforts that are inevitable to ensure recovery of the endangered species at Fort Hunter Liggett.
Keywords: arroyo toad, life history, habitat assessment, breeding habitat, restoration, Fort Hunter Liggett, San Antonio River.
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Acknowledgments
This research could not have been possible without the help and support of my friends, family, coworkers, and committee members. I would like to thank Darlene Woodbury, Kimberly Guilliam, and Jason Bachiero, Albion Environmental, Inc. wildlife biologists, for assisting in data collection, Liz Clark, Department of Defense Wildlife Biologist, and Wally Haussamen, Department of Defense Natural Resource Manager, for providing installation documents and personal support, Laura Eliassen, Fort Hunter Liggett Range and Training Lands Assessment Coordinator, and Tom Mastin, California Polytechnic State University professor, for guiding me through the technical aspects of GIS analysis and software use, and my committee members, Dr. David Pilliod, Dr. Emily Taylor, and Dr. Scott Steinmaus, for helping me focus my work in such a way that the final product may ultimately benefit conservation of the endangered arroyo toad. I cannot begin to describe my deepest gratitude for the constant encouragement and guidance that my committee advisor, Dr. David Pilliod, provided throughout this experience. This work may never have been completed if I hadn’t introduced him to the arroyo toads at Fort Hunter Liggett.
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Table of Contents
List of Tables ................................................................................................................................ viii
List of Figures ............................................................................................................................... viii
CHAPTER 1: Description of Target Species, Study Area, and Goals for the Study ......... 1
Introduction ...................................................................................................................................... 1
Species Account ............................................................................................................................... 3
Study Area ....................................................................................................................................... 5
Investigations ................................................................................................................................... 6
References ........................................................................................................................................ 8
CHAPTER 2: Arroyo Toad Life History, Status, and Population Threats Specific to Fort Hunter Liggett, California ............................................................................................................. 9
Abstract ............................................................................................................................................ 9
Introduction ...................................................................................................................................... 9
Study Area ..................................................................................................................................... 11
Methods ......................................................................................................................................... 13
Results ............................................................................................................................................ 17
Habitat Features ......................................................................................................................... 17
Adult Activity and Behavior ...................................................................................................... 19
Larval Development ................................................................................................................... 21
Juvenile Activity ........................................................................................................................ 24
Population Status and Current Threats....................................................................................... 25
Discussion ...................................................................................................................................... 27
Management Implications .............................................................................................................. 33
References ...................................................................................................................................... 35
CHAPTER 3: Loss of Arroyo Toad Breeding Habitat at Fort Hunter Liggett and Investigation of Potential Environmental and Anthropogenic Influences Accelerating Habitat Conversion ..................................................................................................................... 37
Abstract .......................................................................................................................................... 37
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Introduction .................................................................................................................................... 37
Study Area ..................................................................................................................................... 39
Methods ......................................................................................................................................... 42
Aerial Imagery Analysis ............................................................................................................ 42
Satellite Data Analysis ............................................................................................................... 42
Environmental and Anthropogenic Influences .......................................................................... 45
Results ............................................................................................................................................ 47
Aerial Imagery Analysis ............................................................................................................ 47
Satellite Data Analysis ............................................................................................................... 49
Environmental and Anthropogenic Influences .......................................................................... 53
Discussion ...................................................................................................................................... 60
Management Implications .............................................................................................................. 64
References ...................................................................................................................................... 66
CHAPTER 4: Habitat Restoration for Arroyo Toad Conservation at Fort Hunter Liggett, California ....................................................................................................................................... 68
Introduction .................................................................................................................................... 68
Develop a restoration strategy ....................................................................................................... 70
Monitor and evaluate restoration effectiveness ............................................................................. 71
Incorporate and adaptive management approach ........................................................................... 72
Summary and Conclusion .............................................................................................................. 73
References ...................................................................................................................................... 73
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List of Tables
Table 3.1: Summary of Fort Hunter Liggett San Antonio Valley annual (July-June) precipitation (cm) for 1987-1997 and for 1997-2007. ...................................................... 55
List of Figures
Figure 1.1: Arroyo toad distribution in California. .............................................................. 2
Figure 1.2: Fort Hunter Liggett arroyo toads: A) adult, B) newly hatched larvae, C) maturing larva, D) newly metamorphosed juvenile. .......................................................... 4
Figure 2.1: Arroyo toad range on Fort Hunter Liggett, subdivided by 200-m survey sections. .......................................................................................................................... 13
Figure 2.2: Percentage of surveyed arroyo toad oviposition sites in 2004-2008 exibiting specific characteristics: A) location relative to stream channel; B) dominant substrate; C) estimated coverage of emergent vegetation ; D) estimated coverage of shade; E) classification of bank vegetation in vicinity; F) estimated coverage of algae. ................. 18
Figure 2.3: Illustration of Fort Hunter Liggett arroyo toad larvae from egg through metamorphosis. ............................................................................................................... 23
Figure 2.4: Arroyo toad oviposition areas on Fort Hunter Liggett.................................... 26
Figure 2.5: Median and average daily discharge for the San Antonio River at USGS Station 111449900 1987-2007. ....................................................................................... 28
Figure 2.6: Average ambient temperature at 2100 hrs for Fort Hunter Liggett 2002- 2008. ............................................................................................................................... 29
Figure 2.7: Salinas River in San Luis Obispo County. .................................................... 31
Figure 2.8: Average precipitation for Fort Hunter Liggett and Paso Robles. ................... 32
Figure 2.9: Average maximum temperature per month for Fort Hunter Liggett and Paso Robles. ................................................................................................................... 32
Figure 2.10: Daily discharge rates for the San Antonio and Salinas rivers in 2005. ....... 33
Figure 3.1: Arroyo Toad Habitat in the San Antonio River at Fort Hunter Liggett, with corresponding training areas and satellite analysis area. ............................................... 41
Figure 3.2: Training Area 22 in the vicinity of Alice Road in A) 1949 exhibiting expansive riparian woodlands, B) 1963 with extensive tree loss and burned upland terraces (arrows), C) 1994 with two beaver dams (arrows) and slight vegetation recovery along stream banks, and D) in 2002 with two newly established beaver dams
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(green arrows) and former 1994 beaver dams (orange arrows) and increasing bank vegetation. ....................................................................................................................... 48
Figure 3.3: Percentage of bare ground in arroyo toad habitat at Fort Hunter Liggett in 1987, 1997 and 2007. ..................................................................................................... 49
Figure 3.4: Percentage of dense riparian vegetation in arroyo toad habitat at Fort Hunter Liggett in 1987, 1997, and 2007. ......................................................................... 50
Figure 3.5: Percentage of decreased, increased, and unchanged bare ground coverage in arroyo toad habitat at Fort Hunter Liggett from 1987-2007. ........................ 51
Figure 3.6: Percentage of increased, decreased, and unchanged dense riparian vegetation coverage in arroyo toad habitat at Fort Hunter Liggett from 1987-2007. ....... 52
Figure 3.7: Percentage of increased dense riparian vegetation within 100 meters of decreased bare ground and percentage of area where increased dense riparian vegetation overlaps with decreased bare ground in arroyo toad habitat at Fort Hunter Liggett from 1987-2007. .................................................................................................. 53
Figure 3.8. San Antonio River course in 2007 and 1994 with increased dense riparian vegetation from 1987-2007 in Training Area 22 at Fort Hunter Liggett. .......................... 54
Table 3.1: Summary of Fort Hunter Liggett San Antonio Valley annual (July-June) precipitation (cm) for 1987-1997 and for 1997-2007. ...................................................... 55
Figure 3.9: Concrete crossing on Del Venturi Road, Fort Hunter Liggett in A) 2004 following removal of stream vegetation, and in B) 2008 with stream channel occluded by vegetation. .................................................................................................................. 58
Figure 3.10: Concrete crossing on the Multi-Purpose Range Complex, Fort Hunter Liggett in A) 2003 with minimal vegetation growth and in B) 2008 with excessive vegetation growth. ........................................................................................................... 60
Figure 3.11: Three target areas for habitat restoration of arroyo toad habitat at Fort Hunter Liggett based upon presence of increased dense riparian vegetation and decreased bare ground from 1987-2007, coupled with reduced breeding activity from 2005-2008. ...................................................................................................................... 62
CHAPTER 1: Description of Target Species, Study Area, and Goals for the Study
Introduction
The arroyo toad (Anaxyrus californicus) is a federally endangered species that
inhabits coastal and desert drainages within the regions of southern California and Baja
California (US Fish and Wildlife Service 1999) (Figure 1.1). The species has been
extirpated from approximately two-thirds of its range due to loss of habitat and
hydrological alterations to stream systems as a result of dam construction and flood
control (Jennings and Hayes 1994). Introduced species, such as bullfrogs (Lithobates
catesbeianus) and green sunfish (Leopmis cyanellus), increase predation pressure and
contribute to the decline of the species. In systems where arroyo toads occur, survival is
impacted by recreational activities, such as off-road vehicle and excessive foot traffic,
water diversion or degradation from agricultural practices, channel stabilization from
exotic plants, and cattle grazing (US Fish and Wildlife Service 1999).
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Figure 1.1: Arroyo toad distribution in California.
In 1996, arroyo toads were discovered at Fort Hunter Liggett (FHL) in Monterey
County, California in the San Antonio River and were later determined to occupy 26.7
km of river from approximately 2.4 km northwest of the San Antonio Mission downstream
to the alluvial floodplain above the San Antonio Reservoir. This isolated population
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occurs at the northernmost edge of the species range (Figure 1.1). The next extant
population is in the Sisquoc River in Santa Barbara County approximately 150 km to the
south (US Fish and Wildlife Service 1999). Arroyo toad museum specimens were
collected from the Salinas River in Santa Margarita, San Luis Obispo County in 1936
(Miller and Miller 1936), however occurrence of the species in that county has not been
documented since (US Fish and Wildlife Service 1999).
Species Account
Adults are 5-8 cm in length from snout to urostyle (Figure 2.1 a). The dorsum is
rough in texture and is generally light tan to olive in color (variable based on dominant
substrate) and the vent is pale or white and lacks markings (Stebbins 1985). A v-shaped
bar extends across the eyelids. The parotid glands are oval. Upon hatching, larvae are
jet black and become dark to lightly mottled with age (Figure 2.1 b-c). The venter is pale
or white without markings and the tail is banded. Newly metamorphosed juveniles are
approximately 12-15 mm, resemble adults in appearance, and are heavily cryptic (Figure
1.2 d) (Sweet 1992).
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Figure 1.2: Fort Hunter Liggett arroyo toads: A) adult, B) newly hatched larvae, C)
maturing larva, D) newly metamorphosed juvenile.
Arroyo toads favor seasonal systems that experience winter scouring of
vegetation and that are often dry during late summer and fall months. Arroyo toads are
nocturnal, forage and burrow in open floodplains and terraces, and breed in slow moving
or pooling shallow water in areas open to the sky and with little emergent vegetation.
The species is relatively sedentary and is not known to travel great distances over open
terrain in search of new systems (Sweet and Sullivan 2005).
Breeding occurs in the spring, and is signaled by male advertisement for
females. Vocalizations generally occur from about one hour past sunset to midnight.
Adult males vocalize in streams in areas of shallow water typically with a gently sloping
sand bank. The call is a one-note trill that lasts several seconds. After locating a male of
choice, a gravid female, stimulated by amplexis, will deposit a single, double-stranded
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egg mass in the shallow water (< 10 cm). Females breed once per season whereas
males will breed multiple times as opportunity provides. Larvae hatch 3-5 days after
oviposition and remain congregated along the water’s edge in shallow water. As the
larvae develop, they begin to use algal mats or detritus in deeper water for cover. After
metamorphosis, juveniles remain close to water, but begin to burrow in sand within
weeks. By early fall, most arroyo toads disperse into the uplands and spend most of the
winter burrowed underground, emerging every few days to hydrate and forage (Sweet
1992).
Study Area
FHL is an US Army Combat Support Training Center located in southern
Monterey County, California, approximately 37 km southwest from King City and 72 km
northwest of Paso Robles. The Los Padres National Forest borders the installation to the
north and west, and Jolon and Lockwood Valley border the installation to the east. FHL
encompasses nearly 66,000 ha of the Santa Lucia Mountains. Vegetation communities
include foothill pine (Pinus sabiniana), valley oak (Quercus lobata), chamise
(Adenostoma fasciculatum), interior live oak (Quercus wislizeni), and California annual
grassland. Two major river valleys traverse the installation from the northwest to the
southeast: the Nacimiento and the San Antonio. The elevation ranges from 237 m at the
San Antonio Reservoir to 1141 m at Alder Peak.
The climate at FHL is Mediterranean; winters are cool and wet, and summers are
hot and dry. Annual precipitation is highly variable. July through June precipitation totals
from 1987 to 2007 ranged from 18 cm (2007) to 117 cm (1998). The mountainous area
on the western boundary generally receives twice as much rainfall as the river valleys.
January and February are typically the most precipitous months. Summer daytime
temperatures average 31-35 o C with highs often exceeding 38˚ C, while winter days
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average 15-18 o C with lows often below freezing. July and August are typically the
warmest months, while December and January are typically the coldest months.
Cattle ranching was the primary land use of FHL lands since the establishment of
Mission San Antonio de Padua in 1771. FHL continued to lease land for grazing until
1991. Other agriculture was introduced to the valley bottoms by Early Americans in the
mid to late 1880’s, as was mineral and rock mining (Mellini and Seavey 1979). In 1940,
the land was purchased from William Randolph Hearst and other private land owners to
serve as a training installation for World War II troops. The installation continues to
provide training for the 40th Mechanized Infantry Division of the California Army National
Guard, Reserve units from several branches of the Armed Forces, and active
components of the Army Rangers, Special Forces, Navy Seabees, Marines, and other
federal, state, and local government agencies.
The 26.7 km of the San Antonio River that arroyo toads occupy is a 5th order
stream. The river varies from narrow, cobble courses to wide, alluvial floodplains. The
channel substrate is predominantly sand and gravel, with periodic exposures of
sandstone bedrock. The bank vegetation is patchy to dense and is dominated by
Fremont cottonwood (Populus fremontii) and mixed willow (Salix spp.) species.
Discharge can exceed 280 m3 per second during winter storm events. Base flow is
below 3 m3 per second during the spring. Much of the river dries or flows underground
during summer and fall months (USGS Station 111449900 data).
Investigations
The goal of my research was to examine the life history of arroyo toads in the
northern portion of their range and investigate the potential threats to population
persistence for this endangered endemic species.
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In Chapter 2, I investigate the behavioral, developmental, and environmental
characteristics of arroyo toads on FHL and identify disparities with southern populations.
Building a life history account of arroyo toads specific to FHL is important for installation
conservation and habitat management efforts, and can be used to guide efforts
attempting to document the species in its historic range in San Luis Obispo County. I
also estimate total suitable breeding habitat at FHL, how it has changed since discovery
of the species, and current threats that may be impacting the population and its habitat.
This essential information is vital to recovery efforts of the endangered species at FHL.
In Chapter 3, I investigate habitat conversion within the range of arroyo toads in
the San Antonio River and its relation to loss of oviposition sites on FHL. Over the past
two decades, many reaches of the river have been altered by encroaching riparian
vegetation, stabilizing the channel and reducing available shallow pools necessary for
arroyo toad breeding activity. I examine aerial imagery to assess stream qualities and
habitat of the river through military ownership of the land, and investigate potential
environmental and anthropogenic influences that may have impacted the stream system.
I use satellite data to quantify loss of bare ground and conversion to dense riparian
vegetation, and identify candidate areas for restoration. Because of the narrow
distribution and the limited breeding habitat of this isolated population, there is a need for
information on how human activities influence critical habitats and either increase
extinction risk or decrease likelihood of recovery.
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References
Jennings, M.R. and M.P. Hayes. 1994. Amphibian and reptile species of special concern in California. California Department of Fish and Game, Inland Fisheries Division, Rancho Cordova, California. Contract Number 8023. 255 pp.
Mellini, P. and K.L. Seavey. 1979. Historic Preservation Field School, Jolon, California July 30 – August 10, 1979. A rural preservation project sponsored by the San Antonio Valley Historical Association, Monterey County Department of Parks, with support from the Hearst Foundation. Department of History, Sonoma State University, Department of Architecture, California Polytechnic State University, San Luis Obispo.
Miller, L. and A.H. Miller. 1936. The northward occurrence of Bufo californicus in California. Copeia 1936:176.
Stebbins, R.C. 1985. A field guide to western reptiles and amphibians. Second edition, revised. Houghton-Mifflin Company, Boston, Massachusetts. xiv+336 pp.
Sweet, S.S and B.K. Sullivan. 2005. Arroyo toad in Lannoo, M., ed., Amphibian Declines- The Conservation Status of United States Species: Berkeley, CA, University of California Press, p. 396-400
Sweet, S.S. 1992. Ecology and status of the arroyo toad (Bufo microscaphus californicus) on the Los Padres National Forest of southern California, with management recommendations. Report to United States Department of Agriculture, Forest Service, Los Padres National forest, Goleta, California. ii+198pp.
US Fish and Wildlife Service. 1999. Recovery plan for the arroyo southwestern toad (Bufo microscaphus californicus). US Fish and Wildlife Service, Portland, Oregon. v+71pp.
US Geological Survey Station 111449900. San Antonio River near Lockwood, California. http://nwis.waterdata.usgs.gov/ca/nwis/inventory/?site_no=11149900&
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CHAPTER 2: Arroyo Toad Life History, Status, and Population Threats Specific to Fort Hunter Liggett, California
Abstract
The federally endangered arroyo toad (Anaxyrus californicus), which inhabits the
San Antonio River at Fort Hunter Liggett in Monterey County, California, has adapted to
environmental conditions that may be unique to its northern range. Formation of shallow
pools and increased nightly temperatures in late April initiates commencement of
breeding. Metamorphosis of larvae occurs as the system dries in July. Juveniles and
adults combat extreme summer heat and lack of humidity by taking refuge in abundant
herbaceous and riparian vegetation along stream margins. However, some
environmental conditions may be detrimental to the population. Increased bank
stabilization as a result of encroaching riparian vegetation has created incised channels
in some areas of the San Antonio River, degrading suitable breeding habitat for arroyo
toads. Introduced bullfrogs (Lithobates catesbeianus), which predate arroyo toads, and
American beaver (Castor canadensis), which exacerbate vegetation encroachment and
bank stabilization through dam construction, are both common in the system. These
species profit from the habitat conversion and compromise recovery of arroyo toads at
Fort Hunter Liggett. Appropriate habitat restoration and management is necessary for
the installation to improve conservation of this endangered species.
Introduction
The arroyo Toad (Anaxyrus californicus) is a federally endangered species that
inhabits coastal and desert drainages from Fort Hunter Liggett (FHL) in southern
Monterey County in California to northwestern Baja California in Mexico (US Fish and
Wildlife Service 2001). The species was discovered on FHL in 1996 and determined to
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occupy 26.7 km of the San Antonio River from approximately 2.4 km northwest of
Mission San Antonio de Padua to the river delta above the San Antonio Reservoir.
Suitable habitat for arroyo toads was not located in any other stream system on FHL
(Clark 2000).
Previous to the discovery of arroyo toads at FHL, the northernmost population
occurred in the Sisquoc River in Santa Barbara County, approximately 150 km southeast
of FHL. Three museum specimens were collected from the Salinas River Basin near
Santa Margarita in San Luis Obispo County on June 12, 1936 (Miller and Miller 1936),
however the species has not since been detected in the county (US Fish and Wildlife
Service 1999a). The arroyo toad population at FHL may have once extended to the
Salinas River but the construction of the San Antonio Dam in 1963 has isolated the
population, likely contracting the extent of the range considerably.
FHL was established in 1940 to serve as a training site for World War II. Prior to
the acquisition of the property, the land had been primarily used for cattle grazing.
Training activity during the 1940’s and 1950’s far exceeded current allowable use. Much
of the landscape was burned and extensive erosion, vegetation loss, and off-road
vehicle traffic is evident in aerial photographs. FHL continued to lease land for cattle
grazing until cessation of the program in 1991. Today military maneuvers are prohibited
in the San Antonio River channel. All projects and activities that may negatively impact
natural resources require review and clearance from the Environmental Division at FHL
(FHL 1996). Upland areas of the San Antonio River are typically used for bivouac or live-
fire range activities. Annual burning of the Multi-Purpose Range Complex is conducted
during spring months to reduce incidence of wildfire that may escape into the riparian
zone of the river. The FHL arroyo toad population is monitored annually as outlined in
the endangered species management plan for the installation (Hancock and Clark 2004).
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Through recent years, I have discovered a few yet significant anomalies
characteristic of the FHL arroyo toad population. To improve management and
protection of the species, I have compiled a life history account of the arroyo toad
population specific to FHL based upon population monitoring and other related studies
conducted since the discovery of the species in 1996. This compilation will not only
benefit the installation, but may provide supplemental species information for other
arroyo toad populations in drainages with similar climate and precipitation, as well as
provide guidance for survey efforts attempting to document arroyo toads in the historic
range of San Luis Obispo County. In addition, I have outlined current threats to the FHL
population and provided direction to assist recovery efforts of the endangered species
on the installation.
Study Area
FHL encompasses nearly 66,000 ha of the Santa Lucia Mountains in southern
Monterey County. The San Antonio River enters the installation near the northwest
boundary and empties into the San Antonio Reservoir in the southeast portion of the
installation. The 26.7 km section of the river in which arroyo toads occupy transverses
the wide plain of the San Antonio River Valley as a 5th order stream, and comprises
intermittent sandy channels and sand bars with low elevation and sandy terraces
adjacent to and between braided channels. The width of the floodplain ranges from 80-
600 m, yet the width of the active river channel averages 10 m during spring months.
The flow of the San Antonio River is seasonal, with surface water present primarily in
winter and spring. During the fall, most flow continues underground, however many
portions of the river remain perennial. The elevation of the river in the arroyo toad range
is 238-317 m. The riparian vegetation canopy is predominately Fremont cottonwood
(Populus fremontii) or mixed willow (Salix spp.) species, and the understory comprises
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mule fat (Baccharis salicifolia), mugwort (Artemisia douglasiana), California rose (Rosa
californica), and California blackberry (Rubus ursinus).
The climate at FHL is characterized as Mediterranean, with cool, wet winters and
hot, dry summers. The average rainfall from 1960 to 2007 is 49 cm, yet annual
precipitation is highly variable. In the past ten years, total rainfall has ranged from 18 cm
(2007) to 117 cm (1998). The average daytime temperatures range from 15-18 o C in the
winter to 31-35 o C in the summer. It is common for summer days to exceed 38 o C and
for winter mornings to drop below freezing. July and August are typically the hottest
months, and December and January are typically the coldest months. Water discharge
in the San Antonio River averages 8.5 m3 per second during the winter months and often
exceeds 56 m3 per second during storm events. The river drops below 3 m3 per second
during early spring months, then flows underground for much of its length during the
summer and fall (USGS Station 111449900 data).
Surveys conducted for this life history compilation encompassed the entire FHL
range of arroyo toads, including upland terraces and adjacent tributaries (Figure 2.1).
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Figure 2.1: Arroyo toad range on Fort Hunter Liggett, subdivided by 200-m survey
sections.
Methods
The information provided in this report was compiled from annual arroyo toad
population monitoring and other related studies conducted on FHL from 1997 through
2008. Initial surveys, following the discovery of arroyo toads during Land Condition
Trend Analysis surveys in 1996, were directed towards defining the population
distribution. Surveys for calling males were conducted in 1997 under the lead of Karen
Swaim at 7 sites along the San Antonio River and one site along Jolon Creek, a tributary
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to the San Antonio River. Surveyors visited each site 1-4 times from March 20 to April
18. Surveys began at least one hour past dusk and lasted 30 to 60 minutes. Surveyors
walked stable grassy banks counting all chorusing arroyo toads.
In 1998, Jones & Stokes Associates, Inc. were contracted to determine relative
abundance and reproductive success of arroyo toads at FHL (Jones & Stokes 1999).
Surveys were conducted 1-3 times at nine locations along the San Antonio River and
two locations along Mission Creek, a tributary of the San Antonio River. Surveys were
conducted between May 26 and July 2 and included nighttime surveys for calling males,
daytime surveys for signs of breeding (i.e., presence of eggs or larvae), and repeated
visits to oviposition sites to determine clutch success. Surveys were conducted following
the guidelines provided by the United States Fish and Wildlife Service (USFWS 1995).
From 1999 to 2008, FHL staff and contracted biologists continued annual
monitoring of arroyo toads in the San Antonio River following guidelines provided by the
USFWS (1999b). Multiple surveys for calling males were conducted in April and May of
each year, and were followed by surveys for oviposition sites May through July. In 2000,
the 26.7 km arroyo toad range within the San Antonio River was subdivided into 200-m
segments used for delineation of surveyed areas. Survey sites for calling males fell upon
segment boundaries and breeding pool surveys were focused on the adjacent upper and
lower 200-m segments (Figure 2.1). Inconsistencies between oviposition sites and male
calling locations prompted an intensified focus on day surveys for oviposition sites in
2003. In 2004, habitat assessments of each surveyed 200-m segment were initiated
which included a classification system for breeding suitability, mapping of fall flowing and
pooling waters, and documentation of beaver activity. In 2008, development of larvae at
6 oviposition sites was tracked at least once a week from hatching through
metamorphosis.
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Most surveyed segments were selected at random each year, although many
segments were specifically chosen in relation to information needed for installation
projects or activities. Surveys for calling males were conducted at least one hour past
sunset and surveyors remained at a distance in which chorusing arroyo toads were
audible, yet undisturbed by human presence (50-300 m). Total numbers of calling males
were recorded at survey sites each night. Surveys for oviposition sites began no earlier
than two weeks following the first chorusing male of the year. Most surveyed segments
were visited once, although beginning in 2006 some oviposition sites were revisited in an
attempt to document larval development and success. Surveyors walked slowly
upstream in water deeper than 0.1 m or on stabilized banks searching for arroyo toad
egg masses or larvae. Beginning in 2002, oviposition sites were documented in a
geographical information system (GIS) and stored with pool and habitat data. Bullfrog
(Lithobates catesbeianus) and American beaver (Castor canadensis) dam locations
were also maintained in a GIS. Numerous photographs were taken of developing larvae,
breeding pools, and habitat.
In 2002 Nancy Sandburg was permitted and funded by the USFWS to conduct
radio-telemetry tracking of arroyo toad movement at FHL with assistance from FHL
contracted biologists. The study area was located between Del Venturi Road and Miller
Ranch crossing and encompassed 6,900 linear m of the San Antonio River. Surveys
were conducted eight times from April 4 through June 14 and included a daytime search
for oviposition sites and a nighttime survey for calling males. Captured adult arroyo
toads were tagged with a passive integrated transponder (PIT) manufactured by AVID
Microchip ID Systems, Incorporated. Surveys and handling of arroyo toads were
conducted in accordance to USFWS protocol and Section 10(a)(1)(A) permits under the
Endangered Species Act (1973). No animals were fitted with radio telemetry devices. A
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final report for survey activities and results was submitted to the USFWS and FHL
(Sandburg 2004).
In 2005, FHL staff and contracted biologists monitored the earthquake retrofit of
Sam Jones Bridge under the USFWS Biological Opinion 1-8-04-F-21. Construction
began August 1 and concluded November 4. Biologists were on-site during all ground
moving and vegetation clearing activities. Monitoring included two daytime and three
nighttime pre-activity surveys, and daily morning and weekly nighttime site clearing
during construction. A total of 6 adult and 53 juvenile arroyo toads were captured and
relocated to areas predetermined to support the species, and at an appropriate distance
from the project area to preclude return to the site. Extensive tracking of juvenile and
adult movement was accomplished through morning surveys, which offered insight to
burrowing habits and dispersal efforts. A final report was submitted to the USFWS
following conclusion of the retrofit project (Hancock 2006).
In 2008, FHL contracted biologists monitored the earthquake retrofit of
Nacimiento Bridge under the USFWS Biological Opinion 1-8-07-F-11R. Construction
activities began August 11 and concluded December 19. Biologists were on-site during
all ground moving and vegetation clearing activities. Monitoring included five daytime
and three nighttime pre-activity surveys, and daily morning and weekly nighttime site
clearing during construction. A total of 19 juvenile arroyo toads were relocated to areas
predetermined to support the species, and at an appropriate distance from the project
area to preclude return to the site. A final report was submitted to the USFWS following
conclusion of the retrofit project (Hancock 2009).
In addition to regular monitoring, all incidental sightings of adults have been
recorded in a GIS. Other monitoring during which valuable documentation of arroyo toad
behavior was obtained included monitoring of: active unimproved water crossings
(2001-2008), vegetation clearing at the Del Venturi concrete crossing (2005), areas
16
following wildfire activity (2004 and 2007), Schoonover Airfield (2006), and petroleum
spill clean-up at Miller Ranch crossing (2008).
Results
Habitat Features
The morphology of the San Antonio River in arroyo toad habitat varies from
exposed sandstone and Monterey shale bedrock, with moderately entrenched banks,
deep pools and dense canopy cover, to wide, sandy alluvial plains with braided channels
and sparse, willow dominated riparian vegetation. Although arroyo toad oviposition sites
have been documented from the uppermost portion of the 26.7 km range to the San
Antonio Reservoir inlet, suitable breeding habitat is incongruous.
Suitable breeding habitat in the San Antonio River contains shallow water (< 30
cm) with low current velocity, and maintains surface water for a minimum of 3 months.
Oviposition sites primarily occur on the margin of the active channel, in pooling water
forming at stream margin, or in isolated pools. Oviposition sites contain sand or gravel
substrates, and less often, cobble or bedrock substrate, have little to no emergent
vegetation and little to no shade despite patchy to dense riparian vegetation on adjacent
banks (Figure 2.2). Aquatic algae does not appear to be relevant to site selection,
however as larvae mature, algal mats become ideal as escape cover. Breeding habitat is
most abundant where the river channel is braided and the riparian vegetation is at mid-
successional stage. In years of above-average precipitation, it is common for oviposition
sites to occur in more vegetated and deeper water (higher water level in the river
reduces available habitat). Oviposition sites are typically associated with a sand bar
and/or a sandy terrace.
17
0
20
40
60
80
100
Streambank Margin
Streambank Pool
Isolated Pool
Open Channel
Channel TerminusPe
rcen
t of T
otal
Ovi
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tion
Site
s
Location Category
A) Oviposition Site Locations
0
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80
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Sand Gravel Cobble Silt BedrockPerc
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vipo
sitio
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tes
Substrate Category
B) Dominant Substrate at Oviposition Sites
0
20
40
60
80
100
None 10-30% 40-60% 70-90% 100%
Perc
ent o
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Coverage Category
C) Estimated Coverage of Emergent Vegetation at Oviposition Sites
0
20
40
60
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None 10-30% 40-60% 70-90% 100%Perc
ent o
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Coverage Category
D) Estimated Shade Obscuring Oviposition Sites
0
20
40
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Vegetative Category
E) Classification of Bank Vegetation in Vicinity of Oviposition Site
0
20
40
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None 10-30% 40-60% 70-90% 100%Perc
ent o
f Tot
al O
vipo
sitio
n Si
tes
Coverage Category
F) Estimated Algal Coverage at Oviposition Sites
Figure 2.2: Percentage of surveyed arroyo toad oviposition sites in 2004-2008
exibiting specific characteristics: A) location relative to stream channel; B)
dominant substrate; C) estimated coverage of emergent vegetation ; D) estimated
coverage of shade; E) classification of bank vegetation in vicinity; F) estimated
coverage of algae.
18
Unsuitable breeding habitat in the San Antonio River lacks shallow pooling water
and typically contains water year-round. The channel in these areas is often entrenched
and lacks sinuosity. Bank vegetation is dense and encroaches into the active channel.
Year round occurrence of predacious bullfrog and introduced beaver is supported in
these areas. Exotic plants such as cattails (Typha spp.) may become dense and occlude
banks to arroyo toad movement.
There are portions of the river in which breeding habitat suitability fluctuates with
annual precipitation patterns, streambed scouring events, and fluvial deposits. These
areas might contain secondary channels that provide ideal breeding habitat conditions in
years with above-average rainfall, or areas that generally lack shallow pooling water
except in years with below-average rainfall. These areas are often associated with sandy
terraces and open floodplains ideal for foraging adults.
Adult Activity and Behavior
The arroyo toad breeding season at FHL is initiated by male vocalization, which
typically begins late April when the river flow has decreased and shallow pools form.
Oviposition generally occurs between the first week of May and mid June, peaking mid
May. If nightly temperatures are unusually warm or if water levels have prematurely
dropped (due to low precipitation) then males may be stimulated to call earlier. These
conditions have not been documented to affect timing of oviposition. The duration of the
breeding season is generally six weeks; deviations are attributed to a combination of
winter precipitation and available forage for development of eggs in females. Breeding
during years with below-average to average rainfall is most abundant and minimal during
extreme drought (observed in 2007 following 18 cm of rain).
Male arroyo toad vocalizations are long, one-note trills which vary in pitch per
individual and last 2-5 seconds. Vocalization intervals increase with proximity to
19
additional vocalizing males. The trill is distinctive and may be heard as far as 300 m
away from its origin at FHL where noise pollution is minimal. Males are vulnerable to
predators when vocalizing, and are hence sensitive to disturbance. Once disrupted, it
may take several minutes for a male to resume calling. A significant drop in temperature
or a rain event will subdue calling activity.
While it is common to locate oviposition sites incontiguous from sites where
chorusing arroyo toads are detected, some males have been identified to exhibit site
fidelity to their selected calling location. Five males identified with a PIT tag were found
in the same location on multiple survey nights. This fidelity to breeding sites may extend
beyond a single breeding season. In 2003 and in 2005 males were identified chorusing
two days following a rain event that elevated the water level creating breeding habitat in
two locations that were previously dry. Both locations were isolated occurrences of
suitable breeding habitat, where adjacent stream channels were unfavorable for arroyo
toads.
Foraging adults are rarely observed at FHL; open, sandy terraces are abundant
providing unrestricted movement and potential for adults to forage without intraspecific
competition. A total of 13 adults from 2001 to 2007 have been sighted outside of the
active river channel. All sightings have been within 200 m of the water. By mid June,
breeding adults retreat from the water. In 2002, the last observance of a mature adult
was June 7.
The hot, dry climate at FHL results in high evaporation of soil moisture. Cool,
damp soil ideal for burrowing occurs close to the waterline and under leaf litter in
vegetated areas. In 2005, 2 adult arroyo toads were unearthed during vegetation
clearing during the bridge earthquake retrofit project on August 2. The mid-successional
vegetation was dense and comprised approximately six cottonwoods (Populus fremontii)
less than 20 feet in height, many small willow clusters (Salix lasiolepis, Salix exigua),
20
mule fat (Baccharis salicifolia) and other herbaceous perennials. The adults were within
10 m of each other, and within 15 m of the water’s edge. An additional five adults were
found foraging in the 1.2 ha project site during monitoring surveys. Surveys earlier that
year documented 5 arroyo toad oviposition sites 25-150 m upstream from the project
location.
Larval Development
Arroyo toad egg strands are laid in shallow water (< 10 cm) that is generally free
of emergent vegetation. Larvae typically hatch within 3 days and are immobile for an
additional 2 days. At approximately 9 days, the larvae begin to disperse, though tend to
remain in close proximity to their natal pool. Metamorphosis occurs within 60 days of
oviposition. The rate of larval development may accelerate in extreme conditions; in
2006, larvae found in an isolated, solar-heated pool on bedrock were estimated to have
achieved metamorphosis in less than 40 days.
Larvae feed on detritus material as well as carrion and slow moving aquatic
insects as opportunity provides. They typically remain in shallow water until
metamorphosis but will flee to deeper water or burrow in sand or algae to escape
predation. Until larvae reach approximately 14 mm in length, larvae may have difficulty
navigating through filamentous algae and are susceptible to desiccation if entangled as
the water recedes. Yet once movement is no longer impeded by algae, large mats
become an important source of cover.
Arroyo toads hatch as jet-black, gilled larvae approximately 3 mm in length. At 9
mm, the gills are absorbed. By 11 mm, the black becomes slightly mottled and gold
barring is present on the tail. At 14 mm, the vent is light and tan patches appear at base
of tail and mid dorsal-laterally. At 21 mm, the mottling is more extensive and the overall
appearance of the larvae is olive to tan in color. By 24 mm, the black mottling is reduced
21
and concentrated on the dorsum and by 29 mm, remains as a single spot near the base
of the tail. At 34 mm, the hind legs are visible from above and by 37 mm are functional.
At this point the black is absent and a faint tan stripe appears between the eyes. From
39-43 mm, the hind legs become more developed, the body shape more defined, and
the front legs erupt. At the onset of metamorphosis, the dorsum is mottled with white and
dark spots, the cranial stripe is prominent, and tail takes on an orange hue as it is
absorbed. Once metamorphosis is complete, juvenile arroyo toads have the coloration
and markings of wet sand. With age, they lighten to the color of dry sand (Figure 2.3).
22
Figure 2.3: Illustration of Fort Hunter Liggett arroyo toad larvae from egg through
metamorphosis.
23
Juvenile Activity
Metamorphosis typically begins mid June and is complete by the end of July.
During the process of metamorphosis, juveniles will remain close to the water’s edge
and hide under drying algal mats or cobbles. Once complete, they disperse along the
shoreline and seek refuge under bank vegetation. Within 2 weeks of metamorphosis, the
juveniles are able to burrow into loose sand. In August diurnal activity is reduced with
most active foraging occurring between 1000 and 1100 hrs. Juveniles will continue to
burrow close to water in sandy, vegetated regions with minimal to no slope. By early
September, the juveniles are entirely nocturnal and by mid September disperse from
their natal grounds. They remain near the riverbank to forage and hydrate, but move
higher into the riparian vegetation to burrow during daytime hours. General activity
decreases substantially by the end of October.
Diurnal juvenile arroyo toads are highly susceptible to predation, and entire
cohorts may be exterminated by foraging predators. Suspected predators at FHL include
killdeer (Charadrius vociferus), Brewer’s blackbird (Euphagus cyanocephalus), green
heron (Butorides virescens), great blue heron (Ardea herodias), two-striped garter snake
(Thamnophis hammondii), aquatic garter snake (Thamnophis atratus zaxanthus), giant
water bug (Abedus sp.), wild turkey (Meleagris gallopavo), raccoon (Procyon lotor),
opossum (Didelphis virginiana), and bullfrogs (Lithobates catesbeianus) which are also
effective predators of adults (observed). Herbaceous bank vegetation, such as water
speedwell (Veronica anagallis-aquatica), introduced white sweet clover (Melilotus alba),
and cobbles serve as important cover for maturing juveniles. Dense herbaceous bank
vegetation increases vital soil moisture and decreases soil temperature, which at FHL
can reach temperatures in excess of 60° C on exposed sand. After dispersal, it is
common to find juvenile tracks exiting and entering dense stands of riparian vegetation,
even those bordered by dense thatch of yellow star-thistle (Centaurea solstitialis).
24
Population Status and Current Threats
Since surveys began in 1997, arroyo toads have been estimated to utilize 75% of
the 26.7 km range for oviposition. Since the last comprehensive survey conducted in
2005, utilized habitat has been reduced to 61%. Most of the area not utilized by the
species lies in the uppermost 5 km of their range; oviposition sites have not been
detected in this region since 2004 (Figure 2.4). Natural riparian vegetation succession
and encroachment into the stream channel is suspected to be the primary cause of this
range reduction. Areas where reduced activity has been observed typically contain
narrow, incised channels with little to no braiding and are often occluded by riparian
vegetation. These areas are frequently shaded and deep on at least one side of the
channel. Bank stabilization is prevalent, enabling increased riparian vegetation growth.
Beavers are attracted to these areas and exacerbate vegetation encroachment by
introducing willow cuttings into the stream channel. Beaver activity is common within the
FHL arroyo toad range, however most dams outside of these channelized areas are
breached by winter floods and have little impact on adjacent habitat.
25
Figure 2.4: Arroyo toad oviposition areas on Fort Hunter Liggett.
Bullfrog predation is a serious threat for arroyo toads at FHL, particularly for
vulnerable vocalizing males during the breeding season. Bullfrogs are common at FHL
and their productivity and survivorship is facilitated by the narrowing and deepening of
the active channel in the San Antonio River. Deep, shaded pools in the stream channel
offer ideal breeding habitat for bullfrogs and increase the chance of larval survivorship
through the summer and fall when water recedes. Bullfrogs are most prevalent in the
upper region of the arroyo toad range. The San Antonio River retains 60% of linear
surface water (flowing or pooling) in the 26.7 km range under extreme drought
conditions (measured in 2007 following 18.5 cm of precipitation in the preceding rain
26
year). Based on this estimate of minimum perennial water, there is potential for over-
wintering bullfrogs to survive in more than half of the arroyo toad range.
The FHL arroyo toad population is most stable at the center of its range (Miller
Ranch Crossing to Sam Jones Road), with productivity generally decreasing toward the
periphery; habitat in northernmost portion of the range is marginally suitable for
breeding, while highly suitable habitat in southernmost portion of the range does not
always contain surface water sufficient for annual breeding.
Discussion
The arroyo toad population at FHL as described is similar to those described in
other systems. What is unique about arroyo toads at FHL are timing and duration of
breeding period and larval development. Arroyo toads throughout their range typically
initiate breeding in February for coastal populations and late March to early April for
montane populations, and continues through July (Sweet and Sullivan 2005); FHL
breeding begins late April and concludes mid June. The larval development period for
populations in the Los Padres National Forrest is 72-80 days (Sweet 1992) and 77-97 for
Marine Corps Base Camp Pendleton Populations (Brehm et al. 2004); the FHL
population is 55-60 days.
The breeding season for arroyo toads at FHL is restricted by environmental
constraints that may not be present in other drainages supporting the species.
Commencement of activity is dependent upon the timing of shallow pool production in
the San Antonio River and appropriate nighttime air temperatures, and completion of
metamorphosis is challenged by a drying river system. At FHL, the discharge maximum
for egg strand and larvae survival is estimated to be 2 m3. Annual peak flow of the San
Antonio River typically occurs in February; discharge decreases dramatically from March
to April (USGS Station 111449900 data) and drops below 2 m3 mid to late April (Figure
27
2.5). While shallow pools are beginning to form at this time, ambient evening
temperatures are increasing. Arroyo toads generally do not become active until nightly
temperatures exceed 13° C (Sweet 1992); at FHL, average temperature at 2100 hrs
steadily increase above 13° C by late April (Figure 2.6). Based on this data,
environmental conditions are expected to be appropriate for breeding by the last week in
April, which concurs with FHL survey results.
0
2
4
Mar
ch 1
Mar
ch 7
Mar
ch 1
3M
arch
19
Mar
ch 2
5M
arch
31
Apr
il 6
Apr
il 12
Apr
il 18
Apr
il 24
Apr
il 30
May
6M
ay 1
2M
ay 1
8M
ay 2
4M
ay 3
0Ju
ne 5
June
11
June
17
June
23
June
29
Dis
char
ge in
cub
ic m
eter
s pe
r sec
ond
Day
Median Daily Discharge 1987-2007Average Daily Discharge 1987-2007
Figure 2.5: Median and average daily discharge for the San Antonio River at USGS
Station 111449900 1987-2007.
28
0
13
26
Mar
ch 1
5M
arch
18
Mar
ch 2
1M
arch
24
Mar
ch 2
7M
arch
30
Apr
il 2
Apr
il 5
Apr
il 8
Apr
il 11
Apr
il 14
Apr
il 17
Apr
il 20
Apr
il 23
Apr
il 26
Apr
il 29
May
2M
ay 5
May
8M
ay 1
1M
ay 1
4
Tem
pera
ture
(Cel
cius
)
Day
Average Temperature at 2100 hours 2002-2008
Figure 2.6: Average ambient temperature at 2100 hrs for Fort Hunter Liggett 2002-
2008.
By late June, metamorphosis begins as surface flow ceases throughout much of
the range. By August, most pools that are not supplied year round with surface water
have dried. All arroyo toad larvae have typically completed metamorphosis by this point.
Based on these constraints and timing of breeding, FHL has approximatly 45-90 days of
suitable habitat for developing larvae. It is conceivable that other arroyo toad populations
subject to similar environmental constraints, such as in desert drainages, would respond
with accelarated breeding seasons and larval development.
The riparian vegetation in the San Antonio River is much more extensive than
described in other arroyo toad populations. At FHL, arroyo toads often breed in areas
with isolated sand deposits admist densely vegetated banks with deep, incised
channels. Concentrated scat, which is a potential sign of burrowing activity (Sweet
1992), is often found within stands of sandbar willow (Salix exigua) or other mid-
29
successional riparian growth. While this relationship may be incidental, it is possible that
arroyo toads at FHL seek these protective areas to combat desiccation. If this is a
response to heat and humidity, then we may be able to extrapolate adult behavior based
on studies conducted in inland populations where climate is similar. For example, we
may anticipate estivation burrows and movement to be in closer proximity to the active
river channel, such as reported by Ruben Ramirez (2000, 2001).
It is likely that arroyo toad behavior and development characteristic of FHL would
be consistent with arroyo toads potentially inhabiting the historic range of the Salinas
River in San Luis Obispo County, since climate, precipitation, and river structure is
similar. The Salinas River is fed from headwaters in the mountains of eastern San Luis
Obispo County and flows northwest into Monterey County, emptying into the Monterey
Bay (Figure 2.7). The only dam on the river was built in 1941 establishing the Santa
Margarita Lake (San Luis Obispo County Parks). It was in this region that the only arroyo
toad museum specimens for the county were collected in 1936 (Miller and Miller 1936).
Although the river experienced hydrological changes with the construction of the dam,
areas of suitable habitat for arroyo toads is present through the system from the dam to
the confluence of the Naciemento River in southern Monterey County (personal
observation). Outflow from the Nacimiento Reservoir and the San Antonio Reservoir
(next downstream confluence to the Salinas), is regulated and the resultant hydrological
regime is unsuitable for breeding arroyo toads downstream of these confluences. Within
the area of potential habitat on the Salinas River, precipitation, discharge, ambient air
temperature, and humidity are similar to that of FHL. The average annual rainfall for the
Salinas River for the Paso Robles area (central in potential habitat) is 38.7 cm. Although
average rainfall is less, distribution of precipitation parallels FHL (Figure 2.8). The same
is true of average maximum temperatures for the area (Figure 2.9). Data collected from
30
a USGS station in Paso Robles (Station 11147500) indicates that discharge patterns
and rates are similar for both systems (Figure 2.10).
Figure 2.7: Salinas River in San Luis Obispo County.
31
0
5
10
15
July
Aug
ust
Sep
tem
ber
Oct
ober
Nov
embe
r
Dec
embe
r
Janu
ary
Febr
uary
Mar
ch
Apr
il
May
June
Prec
ipita
tion
(cen
timet
ers)
Month
Fort Hunter Liggett Average
Paso Robles Average
Figure 2.8: Average precipitation for Fort Hunter Liggett and Paso Robles.
0
10
20
30
40
50
Janu
ary
Febr
uary
Mar
ch
Apr
il
May
June July
Aug
ust
Tem
pera
ture
(Cel
cius
)
Month
Fort Hunter Liggett Average Maximum
Paso Robles Average Maximum
Figure 2.9: Average maximum temperature per month for Fort Hunter Liggett and
Paso Robles.
32
0
20
40
60
80
100
120
3/1/2005 4/1/2005 5/1/2005 6/1/2005
Dis
char
ge in
cub
ic m
eter
s pe
r sec
ond
Date
San Antonio River Daily DischargeSalinas River Daily Discharge
Figure 2.10: Daily discharge rates for the San Antonio and Salinas rivers in 2005.
Some tributaries to the Salinas River may have isolated suitable habitat, however
most are heavily sedimented and only support surface flow for a few days; flow is
sufficient in some years in the Estrella River, but not consistent enough to support more
than an opportunistic satellite population (USGS Station 11148500 data).
Management Implications
The extensive surveying of arroyo toad breeding habits and larval development
at FHL has provided installation with valuable information that will improve management
and protection of the species. Defining the breeding season and larval development
period in time allows for proper monitoring design and mitigation for projects that may
potentially impact the species. However important data regarding adult habits and
movement is lacking. We may extrapolate behavior exhibited by adults in other systems
with similar climate and precipitation, but until further research is conducted at FHL,
33
definitive answers may not be available. A pit-fall trapping and or radio telemetry tracking
study at FHL would provide the installation with this essential information.
While the information gained at FHL further expands the arroyo toad knowledge
base and may be beneficial for other population managers, it is most advantageous for
surveyors attempting to locate the species within its historic range in the Salinas River or
its tributaries. It should be anticipated that potential populations will begin breeding late
April and that adults may not be detectable past June. Noise pollution may interfere with
detection of chorusing adults in urban settings. Arroyo toad larvae may use emergent
vegetation or algae as cover, increasing difficulty of detection. Surveyors should assume
accelerated larval development; a single clutch may complete metamorphosis by July
and juveniles combating desiccation may no longer be detectable past this point. It is
important to consider vegetated areas as potential breeding habitat as long as shallow
pooling water is present and unobstructed by excessive emergent vegetation. It should
be anticipated that adults will estivate in relatively dense vegetation. And most
importantly, surveyors should acknowledge that entire populations may not breed during
drought conditions. Efforts including these considerations will result in most reliable
presence or absence determinations.
The arroyo toad population at FHL is fortunate not to be subject to many of the
leading threats impacting other populations, such as recreational activities, development,
and agriculture. However, the few threats that the population faces are severe, as
evident by a reduction in the range of oviposition sites since 2005. It is imperative that
FHL implement a restoration plan to slow, halt, or reverse breeding habitat loss to
riparian vegetation succession. Bullfrog or beaver removal from the San Antonio is an
arduous task that may be unachievable due to proximity and high number of thriving
populations in other streams and reservoirs. However these species may be controlled
or their impacts reduced indirectly through habitat management. Reducing channel
34
incision and improving sinuosity would relieve predation pressure of bullfrogs that thrive
in the deep, shaded areas created in the stabilized stream. Established beaver dams not
breached by winter floods should be dismantled to allow natural scouring and
sedimentation of the channel to occur. Prior to the construction of the San Antonio Dam,
the arroyo toad population may have been able to shift occupancy up- or downstream in
response to adverse habitat changes. Now with a restricted range, the population can no
longer accommodate stream stabilization and survivorship is compromised. Improving
breeding habitat will greatly benefit arroyo toads at FHL and increase recovery potential
for this endangered species.
References
Brehm, C.S, A.J. Atkison, and R.N. Fisher. 2004. MCB Camp Pendleton arroyo toad monitoring results, 2003.Prepared for: Wildlife Management Branch, AC/S Environmental Security, Marine Corps Base Camp Pendleton.
Clark, E. R. 2000. Calendar year 1997-1998 annual report for endangered and threatened species at Fort Hunter Liggett, Monterey County, CA. January 2000. Fort Hunter Liggett Directorate of Public Works, Environmental Division, Fort Hunter Liggett, 93928-7090.
Fort Hunter Liggett. 1996. Fort Hunter Liggett Regulation 200-3, Final Draft. Fort Hunter Liggett, CA.
Hancock, J.H and E.R Clark. 2004. Endangered species management plan for arroyo toad (Bufo californicus), Fort Hunter Liggett, California. vi+46pp.
Hancock, J.H. 2006. Sam Jones Bridge earthquake retrofit and rehabilitation, Fort Hunter Liggett. A project completion report pursuant to formal consultation with the US Fish and Wildlife Service, Section 7 of the Endangered Species Act of 1973.
Hancock, J.H. 2009. Arroyo toad monitoring report for the Nacimiento Bridge earthquake retrofit and rehabilitation project 2008.
Jones & Stokes Associates. 1999. Results of field surveys for the arroyo southwestern toad (Bufo microscaphus californicus) at Fort Hunter Liggett in Monterey County. June. (JSA A090). Sacramento, CA. Prepared for Department of the Army, U.S. Army Engineer District, Sacramento, CA.
Miller, L. and A.H. Miller. 1936. The northward occurrence of Bufo californicus in California. Copeia 1936:176.
35
Ramirez R.S. 2000. Arroyo toad (Bufo californicus) radio telemetry study, Little Rock Creek, Los Angeles County, California. Prepared for: USDA Forest Service, Angeles National Forest.
Ramirez R.S. 2001. Arroyo toad (Bufo californicus) radio telemetry study, Little Rock Creek, Los Angeles County, California (Interim Report 2). Prepared for: USDA Forest Service, Angeles National Forest.
Sandburg, N.H. 2004. Assessment of methods and habitat breeding survey results 2002 of the arroyo toad (Bufo californicus) at Fort Hunter Liggett, California.
Sweet, S.S. 1992. Ecology and status of the arroyo toad (Bufo microscaphus californicus) on the Los Padres National Forest of southern California, with management recommendations. Report to United States Department of Agriculture, Forest Service, Los Padres National forest, Goleta, California. ii+198pp.
San Luis Obispo County Parks. Santa Margarita Lake. http://www.slocountyparks.com/activities/santa_margarita.htm
Sweet, S.S and B.K. Sullivan. 2005. Arroyo toad in Lannoo, M., ed., Amphibian Declines- The Conservation Status of United States Species: Berkeley, CA, University of California Press, p. 396-400
US Fish and Wildlife Service. 1995. Survey Protocol for the Arroyo Southwestern Toad. Ventura Fish and Wildlife Office, Ventura, California.
US Fish and Wildlife Service. 1999a. Recovery plan for the arroyo southwestern toad (Bufo microscaphus californicus). US Fish and Wildlife Service, Portland, Oregon. v+71pp.
US Fish and Wildlife Service. 1999b. Recovery survey protocol for the arroyo southwestern Ttad. Ventura Fish and Wildlife Office, Ventura, California.
US Fish and Wildlife Service. 2001. Endangered and threatened wildlife and plants; final designation of critical habitat for the arroyo toad; final rule. Federal Register 66:9414.
US Geological Survey Station 111449900. San Antonio River near Lockwood, California. http://nwis.waterdata.usgs.gov/ca/nwis/inventory/?site_no=11149900&
US Geological Survey Station 11147500. Salinas River near Paso Robles, California. http://nwis.waterdata.usgs.gov/ca/nwis/inventory/?site_no=11147500&
US Geological Survey Station 11148500. Estrella River near Estrella, California. http://nwis.waterdata.usgs.gov/nwis/nwisman/?site_no=11148500&agency_cd=USGS
36
CHAPTER 3: Loss of Arroyo Toad Breeding Habitat at Fort Hunter Liggett and Investigation of Potential Environmental and Anthropogenic Influences Accelerating Habitat Conversion
Abstract
The federally endangered arroyo toad (Anaxyrus Californicus) has lost prime
breeding habitat to vegetation encroachment and bank stabilization in the San Antonio
River at Fort Hunter Liggett. It is estimated that the population currently uses 61% of the
entire range for oviposition; 8% less than what was estimated in the past decade.
Extreme vegetation loss in the riparian channel and floodplains occurred between 1949
and 1963, when military training was at its height. The hydrological impacts of this
vegetation loss may have been masked by heavy cattle grazing and an impacted
groundwater basin from irrigation in the valley, which inhibited vegetation growth in the
San Antonio River. Since cessation of the grazing program in 1991, and recovery of the
groundwater basin from change in agricultural practices, vegetation succession has
proceeded and the channel is now moving towards a stabilized state. Increased dense
riparian vegetation and a loss in bare ground from 1987-2007 estimated from satellite
data suggests that the impacts of these changes are most severe in the upper reaches
of the arroyo toad range. Restoration and management of the habitat are crucial for
conservation of this endangered species at Fort Hunter Liggett.
Introduction
The arroyo toad (Anaxyrus californicus) is a federally endangered species that
inhabits coastal and desert drainages from Fort Hunter Liggett (FHL) in southern
Monterey County in California to northwestern Baja California in Mexico (US Fish and
Wildlife Service 2001). The species was discovered on FHL in 1996 and determined to
occupy 26.7 km of the San Antonio River from approximately 2.4 km northwest of
37
Mission San Antonio de Padua to the river delta above the San Antonio Reservoir. The
San Antonio Reservoir dam was constructed in 1963, which isolated a population of
arroyo toads that likely extended to a historic population in the Salinas River (Miller and
Miller 1936).
Arroyo toads inhabit dynamic stream systems that experience winter flood events
which scour and redistribute sediment, and then diminish surface flow in the spring and
summer, often ceasing flow entirely in the fall. Habitat requirements within these
systems are age specific to arroyo toads. Adults and juveniles require sandy soils to
burrow and open terrain to forage. Egg strands are laid in very shallow water (< 10 cm)
with low current velocity and with little to no emergent vegetation. Developing larvae
remain in shallow, warm water through metamorphosis. Breeding at FHL typically begins
in late April and concludes mid June, and metamorphosis of larvae is generally complete
by August (Chapter 2). While presence of water is required throughout this time frame,
flow exceeding 2 m3 per second is detrimental to egg strands and developing larvae,
thus annual productivity is highly sensitive to late spring storm events or drought
conditions.
FHL was established in 1940 to serve as a training site for World War II. Prior to
the acquisition of the property, the land had been primarily used for cattle grazing.
Training activity during the 1940’s and 1950’s far exceeded current allowable use. Much
of the landscape was burned and extensive erosion, vegetation loss, and off-road
vehicle traffic is evident in aerial photographs. FHL continued to lease land for cattle
grazing until cessation of the program in 1991. Today military maneuvers are prohibited
in the San Antonio River channel. All projects and activities that may negatively impact
natural resources require review and clearance from the Environmental Division at FHL
(FHL 1996). Upland areas of the San Antonio River are typically used for bivouac or live-
fire range activities. Annual burning of the Multi-Purpose Range Complex is conducted
38
during spring months to reduce incidence of wildfire that may escape into the riparian
zone of the river. The FHL arroyo toad population is monitored annually as outlined in
the endangered species management plan for the installation (Hancock and Clark 2004).
Despite current protection measures for the arroyo toad population in the San
Antonio River, a new threat has developed in recent years: a loss of breeding habitat
due to natural succession of the riparian vegetation. Many areas of the river have
become incised and occluded by riparian vegetation, often rendering conditions
unsuitable for breeding arroyo toads. From the initiation of surveys in 1997 following
discovery of the species in 1996, conversion of breeding habitat has been observed and
a decrease in occupation of the range by the species is suspected. Breeding surveys
since 2005 indicate that arroyo toads are utilizing 61% of their range on FHL, and
breeding has not been observed in the uppermost 5 km of their range since 2004
(Chapter 2). Whether these changes are from natural processes (i.e. precipitation
patterns, lack of flood events), or from anthropogenic activities (i.e. grazing, control
burning), understanding the source of these changes is crucial in devising a plan for
restoration and management of the habitat to protect arroyo toads at FHL. To investigate
habitat conversion in the San Antonio River and to evaluate the severity of the problem, I
used a combination of satellite imagery, aerial photography, precipitation data, river
gauge data, and land use history accounts. I extracted areas of greatest concern and
identified potential problems to begin the process of restoration planning.
Study Area
FHL encompasses nearly 66,000 ha of the Santa Lucia Mountains in southern
Monterey County. The San Antonio River enters the installation near the northwest
boundary and empties into the San Antonio Reservoir in the southeast portion of the
installation. The 26.7 km section of the river in which arroyo toads occupy transverses
39
the wide plain of the San Antonio River Valley as a 5th order stream, and comprises
intermittent sandy channels and sand bars with low elevation and sandy terraces
adjacent to and between braided channels. The width of the floodplain ranges from 80-
600 m, yet the width of the active river channel averages 10 m during spring months.
The flow of the San Antonio River is seasonal, with surface water present primarily in
winter and spring. During the fall, most flow continues underground, however many
portions of the river remain perennial. The elevation of the river in the arroyo toad range
is 238-317 m. The riparian vegetation canopy is predominately Fremont cottonwood
(Populus fremontii) or mixed willow (Salix spp.) species, and the understory comprises
mule fat (Baccharis salicifolia), mugwort (Artemisia douglasiana), California rose (Rosa
californica), and California blackberry (Rubus ursinus).
I utilized the full extent of the FHL arroyo toad range for analysis in this study
(26.7 linear km). This range is almost entirely contained within Training Areas 6B, 16B,
22, 25, and 29; those small portions extending into other training areas were included
into analysis with adjacent training areas since land activity in those areas are similar
(Figure 3.1). Training Areas are arbitrary land units used for management of FHL
training activities. Because activities vary among training areas and may influence
habitat differently, I used “training area” as a factor in my analyses. Satellite analyses
were constrained to the river corridor and floodplains within the arroyo toad range,
however all other analyses extended into upland habitat, which is considered valuable to
arroyo toads.
40
Figure 3.1: Arroyo Toad Habitat in the San Antonio River at Fort Hunter Liggett,
with corresponding training areas and satellite analysis area.
41
Methods
Aerial Imagery Analysis
To determine the relevance of recent changes in arroyo toad habitat, it was
important for me to understand the historic conditions of the river through time. To do
this, I utilized aerial photographs of the installation. FHL has a collection of georectified
aerial photographs of the installation taken by airplane dating as far back as 1929. A set
of photographs were obtained about every 10 years, although some portions of the
installation were not captured during each flight. For analysis of arroyo toad habitat, I
used sets from 1949, 1956, 1963, 1972, 1987, and 1989. I also used 1994 digital
orthoquads of the installation and 2002 IKONOS imagery. I created mosaic files using
ERDAS Imagine software (Leica Geosystems, Norcross, Georgia) for those years whose
pictures were not already combined into a single file. Using ArcMap 9.2 software (ESRI,
Redlands, CA), I visually inspected each year and compared features between years
and compiled a description of features and changes.
Satellite Data Analysis
To examine habitat change over the past 20 years in the FHL arroyo toad range,
I analyzed vegetation reflectance from satellite data. I used Landsat Thematic Mapper 5
data for an area covering southern Monterey County on August 8, 1987, July 2, 1997,
and August 15, 2007. Data included six band layers representing the following
wavelengths: Band 1, 0.45-0.52 um; Band 2, 0.52-0.60 um; Band 3, 0.63-0.69 um; Band
4, 0.76-0.90 um; Band 5, 1.55-1.75 um; Band 7, 2.08-2.35 um. I stacked and subsetted
each set of bands for the 26.7 km analysis area, then georectified the data to IKONOS
imagery using ERDAS Imagine software. I created an area of interest layer that
encompassed the riparian corridor and floodplains of the entire arroyo toad habitat with
the exception of an area that was heavily affected by wildfire in the 2007 imagery;
42
adjacent upland areas were not included to reduce their influence on the pixel values in
the analysis area.
I examined vegetation succession in two separate ways: by total bare ground
and by dense riparian vegetation coverage. Both tell the same story of succession, but
from different perspectives. A loss in bare ground indicates that vegetation succession
has initiated in areas that were previously open, whereas a gain in dense riparian
vegetation indicates the latter stages of succession which typically coincides with
stabilizing of stream banks (personal observation). Open areas are associated with
shallow pooling water, which is necessary for arroyo toad breeding, whereas heavily
vegetated areas accompany deep pooling water which is unsuitable for arroyo toads.
To isolate the pixels that best represented bare ground, I preformed a series of
unsupervised classifications with ERDAS Imagine software using variable numbers of
classes and compared the results with IKONOS data. I found that a classification
scheme with 12 classes best defined the habitat, and that class 12 most accurately
represented bare ground. I created a layer file for each year using this scheme and
recoded the raster attributes so that class 12 became “1” and all other class became “0.”
Using ArcMap 9.2 software with a Spatial Analyst extension, I converted the raster files
to shapefiles and exported the analysis area as a single file.
To isolated pixels that best represented dense riparian vegetation, I first applied
a transformed normalized vegetation index to each year’s data set. The calculation for
this transformation is the difference of near-infrared and visible reflectance values
divided by the total reflectance, which result in enhanced differentiation of vegetation
versus bare ground based on increased cover and/or vigor of the vegetation (Leo et al.,
2000). I repeated the same steps as described for isolating bare ground, although for
this analysis, I found that a classification scheme with 8 classes was appropriate and
class eight best represented dense riparian vegetation.
43
Once I obtained files for bare ground and dense riparian vegetation, I ran a
number of analyses to see how each changed over the past 20 years. To begin, I
calculated pixels into ha (pixel size is 28.5 x 28.5 m), and looked at the percentage of
bare ground and dense riparian vegetation per training area per year. I entered these
data into Minitab (Minitab Inc., State College, Pennsylvania) and conducted a multiple
analysis of variance test to determine a difference in the percent bare ground or dense
riparian vegetation per year and per training area. I used Tukey’s method of comparison
with 95% confidence intervals to identify differing values when the p-value of the test
was below a 0.05 significance level.
Next I looked at transitioning habitat, in particular where areas have experienced
a loss of bare ground followed by a gain in dense riparian vegetation over the course of
20 years. To assess these changes, I used ArcMap 9.2 to overlay the 1987 bare
ground/dense riparian vegetation files with the 2007 files and used clip and erase
functions to create three new files: gain, (portions present in 2007 and absent in 1987),
loss (portions present in 1987 and absent in 2007), and unchanged (portions present in
both 1987 and 2007). I calculated the percent gain and loss for both habitat states per
training area and performed a paired t-test with Minitab to test the hypothesis that there
is no difference between gained and lost areas using a significance level of 0.05.
To evaluate where these changes have been occurring and how it has affected
the arroyo toad breeding population, I identified areas in the landscape that have had a
considerable gain in dense riparian vegetation and/or loss in bare ground; areas that
were largely unchanged or had a relatively equal loss and gain were considered
marginal habitat changes. The most extreme change would be a conversion from bare
ground in 1987 to dense riparian vegetation in 2007. If this were to occur in the vicinity of
a reduction in arroyo toad breeding activity, then I would consider the change to be
adversely affecting the species. Areas where a loss in bare ground occurred in close
44
proximity to a gain in dense riparian vegetation and a reduction in arroyo toad breeding
activity would indicate that a process is underway that is potentially disadvantageous to
the species. I identified these areas of concern as candidate restoration sites. To identify
such areas, I used the select by location tool in ArcMap to highlight I overlaid the files
with 2002 IKONOS imagery in ArcMap to identify areas that experienced a great gain in
dense riparian vegetation and loss in bare ground, where the two occur within 100 m of
each other, and where they intersect. Areas that were barren in 1987 and exhibited
dense riparian vegetation 20 years later suggests accelerated vegetation growth, and
are potential areas of concern. Finally I compared these areas with arroyo toad
oviposition sites occurring in 1998-2008. I identified areas that displayed a considerable
gain in dense riparian vegetation, loss of bare ground, and absence or reduction of
oviposition sites as areas of concern and candidate for restoration.
Environmental and Anthropogenic Influences
Prior to designing a restoration, an understanding of the environmental and
anthropogenic influences affecting vegetation succession in arroyo toad habitat is
crucial. For example, changes in precipitation and or flood events may, over decades,
prevent scouring and create alteration in sediment deposition which may require
aggressive stream bank alteration treatments, whereas a river crossing, affecting only
adjacent habitat may be improved by minor changes. With this in mind, I explored
potential environmental and anthropogenic influences affecting observed changes in the
FHL arroyo toad habitat.
The environmental variables I examined were precipitation, river discharge, and
active channel location. I evaluated precipitation totals and patterns, and river gauge
data to determine whether or not sufficient scouring events have been occurring. I used
precipitation data from the San Antonio Valley Test and Experimental Command
45
Meteorological Station and the Western Regional Climate Center to look at monthly and
annual totals and precipitation patterns. I compared annual totals from 1987-1997 with
totals from 1997-2007 by sorting the values from lowest to highest and performing a
paired t-test to see if there were significant differences in rainfall between the two time
periods (significance level = 0.05). I repeated the same method with annual maximum
discharge collected by the US Geological Survey at Interlake Road (Station 11149900).
Using aerial imagery of the installation in 1987, 1989, 1994, and 2002, and field data
collected in 2007, I created GIS files of the San Antonio River course and identified
portions of the river that have shifted laterally. I overlaid these files with the increased
dense riparian vegetation file and the decreased bare ground file to evaluate the
influence of course change on habitat change.
Finally, I investigated anthropogenic activities to determine their affect on habitat
changes. I examined historical documentation of cattle grazing and cultivation, and
compared records with the satellite data analysis and aerial photographs to investigate
the affect of anthropogenic activities on arroyo toad habitat. I evaluated the effect of
wildfire on vegetation structure in Training Area 22, where escape from annual control
burns is common. I assessed the impacts of the three hardened water crossings within
arroyo toad habitat on the streambed structure through time with aerial imagery (1949,
1956, 1963, 1972, 1987, 1994, and 2002) and determined the extent to which they have
influenced vegetation changes.
46
Results
Aerial Imagery Analysis
The San Antonio River in 1949 was braided and had extensive sandy washes.
Most of the corridor was scattered with large trees and frequently paneled with well
developed woodlands. The 100 year old floodplain was moderately vegetated with scrub
and chaparral, and the upper terraces were frequently cultivated. By 1956, a significant
loss of vegetation was apparent over the range. The most extensive vegetation loss
occurred in Training Area 22, which lost approximately 90% of its large trees by 1963
(Figure 3.2 a-b). Adjacent uplands were heavily burned, which indicates that fire was
likely the source of vegetation loss. Vehicle tracks were abundant and were not confined
to a road system. Recovery of scrub vegetation was observable in 1987, yet tree loss
continued in Training Area 22 (at a reduced rate). Lateral shift of the active river channel
was minor throughout the range until 2002, with the exception of Training Area 22 where
severe vegetation loss increased mobility of the channel. In 1994, portions of the river
began to exhibit large-scale pooling with increased bank vegetation. American beaver
(Castor canadensis) activity, which was previously undetected, was also apparent in
1994. One beaver dam observable in Training Area 22 still exists today (although the
exact location has shifted laterally with the river course (Figure 3.2 c-d). In 2002, bank
vegetation had increased in these stabilized areas, and many areas with extreme lateral
shift resulted in erosion of upland terraces. Overall, habitat changes were most extreme
in Training Area 22, whereas Training Areas 25 and 29 changed very little. Training
Areas 16B and 6B experienced moderate changes, becoming more pronounced from
1994 to 2002.
47
Figure 3.2: Training Area 22 in the vicinity of Alice Road in A) 1949 exhibiting
expansive riparian woodlands, B) 1963 with extensive tree loss and burned upland
terraces (arrows), C) 1994 with two beaver dams (arrows) and slight vegetation
recovery along stream banks, and D) in 2002 with two newly established beaver
dams (green arrows) and former 1994 beaver dams (orange arrows) and
increasing bank vegetation.
48
Satellite Data Analysis
The satellite analysis area was approximately 834 ha and measured 25.1 linear
km. The total bare ground detected by satellite analysis varied per year and per training
area (Figure 3.3). While the total area of bare ground was greatest in 1987, there was no
statistical difference in the total area per year (P = 0.292). Bare ground was significantly
different among the training areas (P = 0.000); Training Area 6B had overall less bare
ground coverage than Training Areas 16B, 22, and 25.
0%
10%
20%
30%
40%
50%
6B 16B 22 25 29 Total
Perc
enta
ge o
f bar
e gr
ound
Training Area
1987
1997
2007
Figure 3.3: Percentage of bare ground in arroyo toad habitat at Fort Hunter Liggett
in 1987, 1997 and 2007.
Dense riparian vegetation composed 12% of the analysis area in 1987, 13% in
1997, and 15% in 2007. While these values increased per decade, results varied per
training area: there was a gain in dense riparian vegetation in Training Areas 6B, 16B,
and 22, and a loss in Training Areas 25 and 29 (Figure 3.4). Despite the gradual
increase in the total area of dense riparian vegetation over the two decades, there was
no statistically significant difference in the totals for the three years (P = 0.927). The total
49
area of dense riparian vegetation was significantly greater in Training Areas 25 and 29
than in the other three training areas (P = 0.008).
0%
20%
40%
60%
80%
100%
6B 16B 22 25 29 Total
Perc
enta
ge o
f den
se ri
paria
n ve
geta
tion
Training Area
1987
1997
2007
Figure 3.4: Percentage of dense riparian vegetation in arroyo toad habitat at Fort
Hunter Liggett in 1987, 1997, and 2007.
The loss in bare gound coverage exceded the gain from 1987-2007, however the
difference in the two was not significant (P = 0.766). Gained and lost bare ground was
variable among the training areas (Figure 3.5).
50
0%
5%
10%
15%
20%
25%
6B 16B 22 25 29 TOTAL
Perc
ent a
naly
sis
area
Training Area
Loss 1987-2007
Gain 1987-2007
No change
Figure 3.5: Percentage of decreased, increased, and unchanged bare ground
coverage in arroyo toad habitat at Fort Hunter Liggett from 1987-2007.
The gain in dense riparian vegetaion was greater than the loss from 1987-2007,
however the difference was not significant (P = 0.907). The overall measurements
however did not reflect the changes among the training areas. There was a considerable
gain in dense riparian vegetation in Training Areas 6B, 16B, and 22, which was balanced
by a loss in Training Areas 25 and 29 (Figure 3.6).
51
0%
10%
20%
30%
40%
50%
6B 16B 22 25 29 TOTAL
Perc
ent a
naly
sis
area
Training Area
Gain 1987-2007
Loss 1987-2007
No change
Figure 3.6: Percentage of increased, decreased, and unchanged dense riparian
vegetation coverage in arroyo toad habitat at Fort Hunter Liggett from 1987-2007.
The most expansive areas of gained dense riparian vegetation occurred in the
upper 4 linear km of Training Area 6B and the upper 2 linear km of Training Area 16B.
The area where gained dense riparian vegetation and lost bare ground occurred within
100 m of each other was greatest in Training Area 16B, and included approximately 10%
of the entire analysis area (Figure 3.7). The total area in which bare ground loss directly
overlapped with gained dense riparian vegetation was 3.7 ha. Many of these overlap
areas occurred within 50 m of an arroyo toad oviposition site. A reduction of oviposition
activity from 2004-2008 occurred in proximity to 20% of the overlap areas, all, with the
exception of one site, within Training Area 16B.
52
0%
10%
20%
30%
40%
50%
6B 16B 22 25 29 TOTAL
Perc
ent a
naly
sis
area
Training Area
100 m proximity
Intersection
Figure 3.7: Percentage of increased dense riparian vegetation within 100 meters of
decreased bare ground and percentage of area where increased dense riparian
vegetation overlaps with decreased bare ground in arroyo toad habitat at Fort
Hunter Liggett from 1987-2007.
Environmental and Anthropogenic Influences
Lateral shift of the active river channel occurred in all training areas from 1987
through 2007. Small linear sections (< 300 m) were common, and typically shifted less
than 50 m laterally. A 1200 linear m section in Training Area 16B shifted 260 m laterally
from 1994 to 2007, but was not associated with the significant increase in dense
vegetation seen elsewhere in the training area. An association between linear shift and
increased dense riparian vegetation is suspected in Training Area 22. Riparian
vegetation in the 2002 Ikonos imagery is most prominent in the 1994 active channel,
however vigor is greater where water currently flows (Figure 3.8). The upland terraces of
this training area are burned annually, and commonly include wildfire from escaping
53
flames. For this reason, vegetation is reduced in areas with no water (former active
channels). There is no indication that lateral shift affects dense vegetation growth unless
accompanied by regular wildfire.
Figure 3.8. San Antonio River course in 2007 and 1994 with increased dense
riparian vegetation from 1987-2007 in Training Area 22 at Fort Hunter Liggett.
54
FHL annual precipitation totals (July-June) were similar from 1987-1997 to 1997-
2007 despite high variability (Table 3.1). A paired t-test of sorted annual totals found no
significant differences between the two ranges of years (P = 0.216). Months with
precipitation greater than 25 cm were more common 1987 through 1997 (5 months
compared to 2 from 1997 through 2007), and may have produced a greater number of
productive scouring events that could have affected vegetation growth in 1997.
Table 3.1: Summary of Fort Hunter Liggett San Antonio Valley annual (July-June)
precipitation (cm) for 1987-1997 and for 1997-2007.
Range of Years
Number of Rain
Years Total
Precipitation Annual
Average Annual
Maximum Annual
Minimum 1987-1997 11 519.84 47.26 91.90 26.30 1997-2007 11 561.26 51.02 119.05 18.54
From field observations, discharge in the San Antonio River exceeding 56 m3 per
second (cms) was deemed significant; this flow was sufficient to dismantle substantial
beaver dams. Annual peak flow for the San Antonio between 1987 and 2007 exceeded
56 cms in 15 of 21 years. Annual peak flow exceeded 141 cms in five years between
1987 and 1997, and in five years between 1997 and 2007. The sorted annual maximum
discharge for 1987-1997 was not significantly different than those for 1997-2007 (P =
0.287).
Cattle grazing had been practiced on FHL lands since the establishment of
Mission San Antonio de Padua in 1771. After military acquisition of the property in 1940,
the installation leased grazing rights from 1942 until 1991. Grazing occurred year round,
and although a 1971 study indicated forage was good, it was determined that FHL was
considerably overstocked and the land could not support continued grazing practices as
55
established (Biswell 1971). Several range studies were conducted in the years following.
Major damage to habitat was noted between 1972 and 1977 (Leopold 1979) and woody
vegetation along stream courses was virtually eliminated (McCullough 1983). Several
recommendations were made to the FHL Command to aid restoration of the habitat:
fencing to exclude cattle from riparian habitat (Menke 1976), reduction in the number of
cattle stocked (Menke 1979), and implementation of seasonal grazing from November
through June (Leopold 1979, Menke 1981). Finally in 1982, seasonal grazing was
implemented and increased canopy growth in the riparian corridors was immediately
observed (Menke 1983, 1985, McCullough 1983). In 1991, a study was conducted to
evaluate existing range conditions and it was determined that despite recovery of
riparian habitat, overall residual forage was low and bare ground was extensive (24.7%
opposed to 6.8% in 1977). Because of the potential for severe negative impacts to the
natural resources, including riparian habitat, it was recommended that FHL should not
permit grazing practices until recovery of the land was achieved (Littlefield 1991). As a
result, grazing practices were temporarily halted for further study. In 1992, a draft
environmental assessment for livestock grazing was prepared, which determined that
mitigated grazing practices would have no significant impact (Jones & Stokes 1992),
however due to conflict with military activities and sensitive resource protection issues,
the document was not finalized and the installation has not reinitiated the program.
Dry farming and irrigated cultivation occurred in the upland terraces of the San
Antonio River during the Mission Era and was continued by American settlers. Although
cattle grazing was the primary agricultural practice in the area, cultivation was common
in the upland terraces of the San Antonio River. While dry farming was the most
common practiced cultivation, there was evidence of irrigated land in the uplands north
of the San Antonio River in Training Area 16B into the early 1960’s. This cultivation is
relatively small (< 10 ha) and likely had no effect on the river hydrology. However, in the
56
1960’s and 1970’s, adjacent lands east of FHL sharing the same groundwater basin
were extensively irrigated, which substantially lowered the groundwater table (Nacitone
Watersheds Steering Committee and Central Coast Salmon Enhancement, Inc. 2008).
Water elevation began to recover in the 1980’s and leveled in 1998; the groundwater
elevation rose approximately 14 m from 1987-1997. This increase in groundwater
elevation may have increased surface water, positively affecting vegetation growth from
1997 through 2007.
Fire has been utilized by the Army since acquisition of the land, and remains an
important land management tool for FHL today. Due to low precipitation, high summer
heat, and low humidity, wildfire as a result of military activity is inevitable. To prevent
such incidences which disrupt training exercises, control burns are conducted during the
late spring to reduce fuel load. Annual burns are conducted on the live-fire ranges in
Training Area 22. Although the San Antonio River corridor is not intentionally burned, fire
often escapes into the riparian zone. As a result, the vegetation in this training area is
maintained primarily within a mid-successional growth state. From 1998-2007, an
average 27% of the analysis area in Training Area 22 was affected by wildfire each year.
Already determined with the evaluation of lateral shift of the active channel, dense
vegetation occurs only where water is present (Figure 3.8). While fire is beneficial in
reducing the negative impacts of increased dense vegetation growth, it also promotes
erosion and colonization of invasive plant species, such as salt cedar (Tamarix
parviflora) and yellow star-thistle (Centaurea solstitialis) which are widespread in
Training Area 22.
There are three concrete water crossings in the arroyo toad range on FHL: Del
Venturi Road in Training Area 6B, Nacimiento-Fergusson Road in Training Area 16B,
and the center lane of the Multi-Purpose Range Complex (MPRC) in Training Area 22.
Each crossing affects upstream and downstream streambed and vegetation structure,
57
but in varying ways. The Del Venturi crossing has high sediment load encouraging
vegetation growth in the channel up- and downstream. From 1987-2007, the upstream
vegetation has encroached on the eastern bank constricting water flow to half the
original channel width. Downstream, vegetation completely occludes the channel for
approximately 60 m. This site was formerly quarried for cobble and was cleared annually
until 1997 when arroyo toads were discovered occupying the area. Although this section
was not analyzed on the satellite data due to the 2007 burn, increased vegetation growth
is apparent on aerial imagery from 1994 to 2002. In February of 2004, the vegetation
downstream of the crossing was removed in order to preserve the structural integrity of
the crossing during high winter flows; four years later no evidence of such activity is
discernable (Figure 3.9). Further downstream the channel is deep and the banks are
entrenched. In 2003, an arroyo toad oviposition site was detected 280 m downstream of
the crossing. Oviposition has not been observed in this location since; the next proximal
site was detected in 2008, 620 m downstream of the crossing.
Figure 3.9: Concrete crossing on Del Venturi Road, Fort Hunter Liggett in A) 2004
following removal of stream vegetation, and in B) 2008 with stream channel
occluded by vegetation.
58
Sedimentation and vegetation encroachment on the upstream southwestern
bank of the Nacimiento-Fergusson concrete crossing has resulted in a reduction of the
channel to nearly half its original width. This vegetated bank is entrenched and the
channel is relatively deep. A plunge-pool exists downstream of the crossing and water
flow is constricted to the extreme southwest edge of the channel. With the exception of
flood events, the channel has not moved from this course since its construction over 45
years ago. Calculated from the satellite data, the next 650 linear m downstream of this
crossing contain the most extensive increase in dense vegetation. Although there are
few isolated locations suitable for arroyo toad oviposition within this segment, most of
the habitat is unsuitable for breeding due to dense vegetation and deep pooling water.
The MPRC crossing was built in the mid 1980’s. This crossing is in a relatively
wide location of the San Antonio River spanning 180 m. The channel is flat, sandy, and
braided and is sparsely vegetated. Water flow was unrestricted by the crossing until a
repair was made in 1997 after winter floods dismantled a 30 m section of the crossing.
The repaired design left this section intentionally lower than the rest of the crossing
drastically constricting water flow and severely affecting streambed conditions up- and
downstream. Vegetation is swiftly encroaching into the upstream channel, and extensive
entrenchment and erosion continues downstream (Figure 3.10). The stream regains its
meandering pattern 800 m downstream. Arroyo toads continue to breed up to this point,
however the number of oviposition sites increase by 50% beyond 800 m downstream.
59
Figure 3.10: Concrete crossing on the Multi-Purpose Range Complex, Fort Hunter
Liggett in A) 2003 with minimal vegetation growth and in B) 2008 with excessive
vegetation growth.
Discussion
The general findings of the analyses support my interpretation of the changes
that I have observed in the system within recent years. Not only has there been a
considerable gain in dense riparian vegetation, the gain is most prominent in Training
Areas 6B, 16B, and 22. In most areas, a gain in dense riparian vegetation results in
decreased arroyo toad breeding activity (Training Areas 6B and 16B). The anomaly
occurs is in Training Area 22; the frequency of oviposition is greatest in this area, yet this
area also contains the most extreme erosion, the most infallible beaver dams, and the
highest occurrence of deep, perennial pools surrounded by thick vegetation. The
difference may be that of the stream course, this area has the greatest potential for
lateral shift. The floodplain is at its widest through much of Training Area 22,
accommodating overbank flooding at established beaver dams and or other occluded
sites. Frequent fire reduces the stabilizing affects of bank vegetation and keeps
secondary channels relatively free of dense vegetation, thereby providing auxiliary
breeding habitat in years of above average rainfall. While this area suffers from the
same issues as upstream, priority for restoration at this location may be secondary.
60
The need for restoration is greatest in Training Area 16B where vegetation
succession is rapidly advancing and the quality of arroyo toad oviposition sites are
deteriorating. This area has the highest occurrence of increased dense riparian
vegetation in proximity and in overlap with loss of bare ground. However, unlike the
upper reaches of Training Area 6B which may have been abandoned by arroyo toads,
and unlike Training Area 22 where the species remains prevalent, activity in this region
is waning. This combination of rapid succession and reduction in breeding activity
warrant the need for restoration to slow, halt, or reverse habitat degradation. Three
locations in this training area are candidate for restoration: downstream of the
Nacimiento-Fergusson crossing, west of the landfill, and from Oro Fino Canyon to
Schoonover Airfield (Figure 3.11).
61
Figure 3.11: Three target areas for habitat restoration of arroyo toad habitat at Fort
Hunter Liggett based upon presence of increased dense riparian vegetation and
decreased bare ground from 1987-2007, coupled with reduced breeding activity
from 2005-2008.
The most striking discovery during my research was that the San Antonio River
was once much more vegetated than it is currently. The 1949 aerial imagery shows
62
extensive riparian woodlands throughout the entire FHL arroyo toad range; today’s open
washes and floodplains were once rich with expansive scrub vegetation. Intuition would
guide that recovery of vegetation in the system would bring it back to its previous state.
However we know that something deleterious is occurring by evidence of a retracting
breeding range. It may be in the type of vegetation recovery that we are witnessing and
where it is occurring. In 1949, the channels were wide and flat, allowing the stream to
meander from bank to bank. Today that sinuosity has decreased and vegetation is more
prominent in the active channel itself. Occlusion of the channel and stabilization of the
banks have consumed shallow pooling areas that may have once been abundant.
While gained dense riparian growth and loss of bare ground in the past 20 years
can be associated with degradation of habitat, the origin of this change likely extended
much farther back in time. It is unquestionable that the most momentous alteration
occurred when the San Antonio River Valley lost extensive riparian woodland and scrub
habitat between 1949 and 1963, destabilizing the river system. It was during this time
arroyo toad habitat was imperiled. As cattle grazed, and groundwater was being
compromised by farming in the valley, the river appeared stable under the artificial
conditions, masking the affects of the changed hydrology and sedimentation patterns.
Presently, with no riparian vegetation growth control, natural succession is occurring and
the channel is stabilizing. Fire, likely the cause of the devastating vegetation loss, is now
responsible for maintaining suitable arroyo toad habitat, as is evident in Training Area
22. Precipitation and river discharge typical for this region may not be sufficient to
counteract the channelization, incision, and erosion so prevalent through the affected
areas.
There was no indication that precipitation or river flow was unusual during the
past 20 years, so the rate of vegetation growth should be stable for the area. Cessation
of cattle grazing and groundwater recovery from intensive farming in the valley likely had
63
the greatest widespread impact on vegetation growth, and could potentially account for
accelerated vegetation growth in localized areas. Hardened water crossings have
negatively impacted adjacent habitat, but are not suspect of widespread channel
stabilization, incision, and erosion. Fire, which is culprit to such channel features, also
tends to counteract deleterious effects of vegetation growth. It is conceivable that
degradation of the habitat has ensued due to a combination of factors, both
environmental and anthropogenic. Likely, typical storm events at FHL are not sufficient
to scour the system without the added grazing pressure which reduces the stabilizing
effects of the riparian vegetation. Perhaps the San Antonio River is stabilizing to a
natural course defined by the geomorphology of the system.
Management Implications
Deleterious effects of a reduction in range or loss of suitable breeding habitat are
compounded at FHL with isolation and range restriction from natural barriers. A
constricted population is susceptible to outbreaks of lethal pathogens and extinction
potential is greater with a catastrophic event such as a severe drought spanning multiple
years. Without immigration from satellite populations, recovery from such an event is
unlikely. As a result, any habitat loss should be regarded with great concern. Arroyo toad
habitat at FHL, which was compromised by the construction of the San Antonio
Reservoir, has experienced localized areas of degradation, fragmentation, and
constriction. In addition, channel stabilization and incision promote deep pooling water,
which in turn provide essential habitat for bullfrog reproduction and survival. Since
bullfrogs occupy all reservoirs and most stream systems on FHL, means of exclusion of
the species from the San Antonio River is impractical. The most feasible method of
bullfrog control is through habitat restoration.
64
To design an appropriate streambed restoration and maintenance plan, FHL
would need to consider geomorphologic conditions of the San Antonio River (Rosgen
1997). Restoration should begin at selected areas in which an alteration may be an
immediate benefit to arroyo toads, specifically those areas outlined in Training Area 16B
(Figure 3.11). Additional restoration would be beneficial in the vicinity of the three
hardened water crossings or where stream stabilization and incision has lead to extreme
erosion. An approach to restoration and applied treatments should consider arroyo toad
habits and utilization of riparian vegetation. Vegetation removal on sandy banks or
floodplains is not advisable, for these are areas in which adults may be burrowed.
Rather passive treatments such as brush revetments at erosion sites to slow water
velocity or wattle siltation fences to redirect flow and promote sediment deposition.
Another treatment that may be beneficial is the removal of beaver dams prior to winter
floods to assist scouring affects of the high water flow.
During the past two centuries cattle grazing may have been an unintended
means of maintaining arroyo toad habitat suitability by suppressing vegetative growth
and allowing lateral shift, winter scouring, and alluvial deposits. While proper utilization
of cattle grazing as a means to maintain mid-successional riparian vegetation may be
potentially beneficial, re-establishment of a grazing program at FHL is a low priority due
to complexity of needed management coupled with increased military activities. If it were
to be reinstated, it is likely that leased lands would be significantly smaller than previous,
and sensitive areas, such as riparian corridors, would be excluded from grazing areas. In
the absence of such vegetation manipulation, the San Antonio River can be expected to
become more incised, the riparian vegetation more dense, and overall more suited for
exotic species, such as bullfrogs and beavers. For the benefit of arroyo toads, it is
imperative that FHL proceed with a restoration plan that will support the continued effort
to protect and provide for the endangered species.
65
References
Biswell, H.H. 1971. Forage growth and utilization survey of the Hunter Liggett Military Reservation.
Fort Hunter Liggett. 1996. Fort Hunter Liggett Regulation 200-3, Final Draft. Fort Hunter Liggett, CA.
Hancock, J.H and E.R Clark. 2004. Endangered species management plan for arroyo toad (Bufo californicus), Fort Hunter Liggett, California. vi+46pp.
Jones & Stokes Associates, Inc. 1992. Preliminary draft environmental assessment for livestock grazing on Fort Hunter Liggett and Fort Ord, Monterey County, California. Prepared for US Army Corps of Engineers.
Leo, L., J.B. Paul, and R.J. Carol. (2000). Estimation of canopy-average surface-specific leaf area using Landsat TM data. Photogrammetric Engineering & Remote Sensing, 66(2), pp.183-191
Leopold, A.S. 1979. The status of wildlife and wildlife habitat on Fort Hunter Liggett, Monterey County. Order No. DAKF03-79-M-7912.
Littlefield, M. 1991. Field evaluation of the lower “B” grazing lease at Fort Hunter Liggett.
McCullough, D.R. 1983. Report on current status of the deer habitat at Fort Hunter Liggett. Prepared for the Department of the Army, Sacramento District, Corps of Engineers. Purchase Order No. DA CA05-83-P-0304.
Menke, J.W. 1976. Analysis of range condition, Fort Hunter Liggett. Prepared for the Sacramento District, Corps of Engineers.
Menke, J.W. 1979. Range and related inventory and condition report, Fort Hunter Liggett. Interim Report. Order No. DACA05-79-P-0034.
Menke, J.W. 1981. A range and related resource inventory and condition study/report with management recommendations for Fort Hunter Liggett, California.
Menke, J.W. 1983. Evaluation of rangeland at Fort Hunter Liggett. Report submitted to US Army Corps of Engineers. Order No. DACA05-83-P-0234.
Menke, J.W. 1985. Rangeland evaluation report on Fort Hunter Liggett.
Miller, L. and A.H. Miller. 1936. The northward occurrence of Bufo californicus in California. Copeia 1936:176.
66
Nacitone Watersheds Steering Committee and Central Coast Salmon Enhancement, Inc. 2008. San Antonio and Nacimiento rivers watershed management plan. Prepared for the Monterey County Water Resources Agency and the State Water Resources Control Board. 177 pp.
Paulson, R.W., E.B. Chase, R.S. Roberts, and D.W. Moody, Compilers, National Water Summary 1988-89-- Hydrologic Events and Floods and Droughts: U.S. Geological Survey Water-Supply Paper 2375, 591 p.
Rosgen, D.L. 1997. A geomorphological approach to restoration of incised rivers.
US Fish and Wildlife Service. 2001. Endangered and threatened wildlife and plants; final designation of critical habitat for the arroyo toad; final rule. Federal Register 66:9414.
US Geological Survey Station 111449900. San Antonio River near Lockwood, California. http://nwis.waterdata.usgs.gov/ca/nwis/inventory/?site_no=11149900&
67
CHAPTER 4: Habitat Restoration for Arroyo Toad Conservation at Fort Hunter Liggett, California
Introduction
The arroyo toad (Anaxyrus californicus) population at Fort Hunter Liggett (FHL) is
a US Fish and Wildlife Service recovery unit for the federally endangered species (US
Fish and Wildlife Service 1999). This is one of 19 populations that must remain self-
sustaining in order for federal delisting of the species. Conservation and protection
measures for arroyo toads are described in an Endangered Species Management Plan
for FHL. This management plan describes activity restrictions in critical habitat for arroyo
toads, but does not describe habitat restoration strategies. The purpose of this chapter is
to outline basic steps to begin planning for restoration of the arroyo toad breeding habitat
at FHL.
Arroyo toad habitat has been protected at FHL since discovery of the species in
1996. The toad population at FHL occupies 26.7 km of the San Antonio River upstream
of the San Antonio Reservoir in Monterey County. The population range is defined by a
steep rocky canyon upstream and the reservoir downstream, which may prevent
movement of the species in or out of this defined range. No other arroyo toad habitat
occurs on the installation. The habitat is protected from all installation activities except
recreation, which is limited to game hunting. Access to the San Antonio River is by foot
only except at designated crossing areas. Cattle grazing, which was a prominent land
practice until cessation of the program in 1991, is no longer permitted on installation
land.
Despite few obvious anthropogenic threats, my research has demonstrated a
contraction in the distribution of arroyo toad oviposition sites over the past four years
coincident with a loss of suitable breeding habitat (Chapter 2). Within the past 20 years,
68
the braided system of the San Antonio River has become moderately entrenched with
reduced sinuosity. The loss of open, sandy reaches has been unfavorable for the arroyo
toad, which requires shallow pooling water for oviposition. Vegetation succession and
bank stabilization has increased the formation of deep pools that support predatory
bullfrogs (Lithobates catesbeianus). Arroyo toads have not been detected in the
northernmost 5 km of the range since 2004 where habitat changes have been most
prominent (Chapter 2). Because arroyo toads may only breed a maximum of four years
(Sullivan and Sweet 2005), it is likely that the species no longer occupies those 5 km of
habitat, reducing the occupied range from 26.7 km to approximately 21.7 km (Chapter
2). Continued fragmentation and loss of breeding habitat could potentially lead to a
decline in the population (Fahrig 1998).
To halt or reverse the observed declining trends in arroyo toad oviposition and
breeding habitat availability, I recommend that the installation improve breeding habitat
conditions in the San Antonio River through carefully planned habitat restoration,
monitoring, and adaptive management. Desirable stream restoration would allow for
natural flow and sediment movement processes of the San Antonio River to maintain a
braided system. Not only would this increase available breeding habitat for arroyo toads,
but it would subsequently reduce deep, shaded pooling areas that support bullfrogs.
While a detailed restoration plan is out of scope for this thesis, I outline basic steps to
begin planning for restoration of the arroyo toad breeding habitat at FHL: (1) Develop a
restoration strategy using principles of adaptive management, (2) Monitor stream
geomorphy, riparian vegetation, and arroyo toad oviposition before and after restoration
activities, (3) Document restoration effectiveness and adapt future or ongoing activities
to maximize restoration success based on pre-defined goals.
69
Develop a restoration strategy
An effective restoration plan must begin with a clear objective (Kondolf 1995):
improve arroyo toad breeding habitat in the San Antonio River. Restoration activity
planning will also need to identify what the problem is, where the problem occurs, what
is likely causing that problem, where restoration would be most effective, and what time
or funding limitations might influence restoration design and implementation. The remote
sensing analysis of changes in arroyo toad breeding habitat described in this thesis
(Chapter 3) can be used as a starting point to identify potential problem areas, but a
more detailed field-based assessment of potential and existing suitable habitat may be
necessary. Potential rehabilitation sites may be used to increase continuity along the
river or to restore an area that has recently been degraded where the species is still
likely present. Due to the stochastic geomorphology of rivers, restoration design and
implementation may be unique to each selected site and consider the influence of future
flow patterns, spates, and sediment loads. The dynamic nature of this system requires a
flexible, adaptive approach to restoration. Initially, each restoration project could be
considered an experiment (Kondolf 1995) with ongoing evaluation of success and
adaptability of strategies to continually achieve the defined restoration goals.
Funding will likely be the most limiting factor of implementation of restoration
projects, and thus must also be taken into account at every step of the planning process.
An elaborate restoration project may not be worthwhile if post-project monitoring cannot
be conducted. It may be prudent to begin with small-scale projects, for example
dismantling abandoned beaver (Castor canadensis) dams in the fall or removing
vegetation surrounding concrete crossings. Most beaver dams are destroyed during
winter floods, however few persist and are rebuilt annually. These dams have stabilized
the upstream channel and have promoted successional vegetation growth into the
channel (Chapter 3; Figure 3.2). While the unfavorable up- and downstream effects of
70
the three concrete water crossings in the arroyo toad range may not be nullified without
removal of the necessary crossings, reducing the vegetation surrounding the structures
will reduce upstream sedimentation and increase water velocity during flooding events
and promote vegetation scouring downstream (Chapter 3). Beaver dams may be
dismantled by hand crews and vegetation surrounding crossing may be cleared using an
excavator with a claw attachment perched from the crossing. Both projects may be
conducted by installation personnel.
Monitor and evaluate restoration effectiveness
I recommend quantitative monitoring of the environmental and population
response to restoration treatments (Kondolf and Micheli 1995; Roni et al. 2002; Shields
et al. 2003). Project monitoring prior to and after restoration treatments are imperative to
gauge project success (Kondolf and Micheli 1995). There are two general data sets
needed: stream condition and response, and species condition and response. Baseline
data collected prior to restoration treatments will set parameters for which the measure
of success can be determined during post evaluation (Kondolf 1995). These parameters
need to be identified as soon as possible and incorporated into annual monitoring of the
arroyo toad population and its habitat at FHL. Current annual data collection should be
evaluated and modified to suit information needs in relation to habitat management
objectives. For example, FHL should consider annual oviposition site census for the
entire 26.7 km range. Not only would this provide an estimation of breeding population
size, but it also provides a direct species response to habitat condition. In addition, FHL
may also want to consider including an inventory of aquatic macroinvertebrates, which
could be used as an indicator of stream water quality (Kondolf and Micheli 1995).
Habitat and stream monitoring needs to be repeatable, defensible, and
temporally and spatially scaled to the restoration activity. Cross-section transects are
71
ideal to measure geomorphic and vegetation structure of the channel. Transects should
extend to width of bankfull flow and should be placed appropriately to capture predicted
stream response to restoration treatments (Kondolf and Micheli 1995). The number and
placement of transects will depend upon size of the restoration project and surveyor
effort. Post- monitoring of the environmental response to determine effect of restoration
treatments will likely require multiple years of data collection. Due to the variability in the
strength of flood events in the San Antonio River (Chapter 3), data collection should
continue for at least 10 years to ensure that the effects of the treatment are tested after
at least one major flood event (Kondolf and Micheli 1995). Data collection need not be
every year, however collection should continue in the immediate years following
treatment and after a defined threshold flood event (Kondolf and Micheli 1995). This
threshold, or “effective discharge,” can be estimated using discharge records from the
US Geological Survey gauge on Interlake Road (site 11149900) and the baseline
geomorphic data (Shields et al. 2003).
Incorporate and adaptive management approach
Documentation of restoration planning, actions, and environmental response,
whether determined successful or not, is critical for developing further conservation
strategies and using an adaptive management approach to arroyo toad habitat
restoration at FHL (Kondolf 1995). Every effort to improve breeding habitat regardless of
scale, should be regarded as an opportunity to gain vital information about the San
Antonio River behavior and thus be treated equally when considering pre- and post-
treatment monitoring evaluation of the habitat at the project site. Not only will such
documentation aid FHL, but it may provide direction for other arroyo toad habitat
restorations projects outside of the installation.
72
Summary and Conclusion
FHL has been protecting the arroyo toad from adverse installation activities since
the discovery of the species in 1996, and continues to improve conservation and
protection strategies. In this unique situation at FHL, simply fencing off the habitat will
not serve to protect the species; the species needs suitable habitat restored in areas
where human activities have resulting in loss or degradation of breeding habitat. Natural
vegetation succession and stream stabilization is replacing the once braided system with
narrow, incised channels and deep pooling regions more suited for bullfrogs.
Unfortunately halting succession is not an easy fix. Maintaining the system to favor
arroyo toad breeding habitat will likely be an ongoing effort. The installation may need to
experiment with various techniques to find one that is effective yet has low impact to
arroyo toads. However it is certain that conservation and recovery of the arroyo toad
population at FHL will not be achievable without active vegetation and stream
management.
References
Fahrig, L. 1998. When does fragmentation of breeding habitat affect population survival? Ecological Modelling 105 (1998) 273-292.
Kondolf, G.M. 1995. Five elements for effective evaluation of stream restoration. Restoration Ecology Vol. 3 No. 2, pp 133-136.
Kondolf, G.M. and E.R. Micheli. 1995. Evaluating stream restoration projects. Environmental Management Vol. 19, No. 1, pp. 1-15.
Roni, P., T.J. Beechie, R.E. Bilby, F.E. Leonetti, M.M. Pollock, and G.R. Pess. 2002. A review of stream restoration techniques and a hierarchical strategy for prioritizing restoration in Pacific Northwest watersheds. North American Journal of Fisheries Management 22:1-20, 2002. American Fisheries Society 2002.
Shields, F.D., R.R. Copeland, P.C. Klingeman, M.W. Doyle, and A. Simon. 2003. Design for stream restoration. Journal of Hydraulic Engineering.
Sweet, S.S and B.K. Sullivan. 2005. Arroyo toad in Lannoo, M., ed., Amphibian Declines- The Conservation Status of United States Species: Berkeley, CA, University of California Press, p. 396-400
73
74
US Fish and Wildlife Service. 1999. Recovery plan for the arroyo southwestern toad (Bufo microscaphus californicus). US Fish and Wildlife Service, Portland, Oregon. v+71pp.